Compositions and methods for regulating the kinase domain of receptor tyrosine kinases

ABSTRACT

The present invention relates to binding pockets of receptor tyrosine kinases (RTKs). The binding pockets may regulate the kinase domain of the receptor tyrosine kinases. In particular, the invention relates to a crystal comprising a binding pocket of a receptor tyrosine kinase that regulates the kinase domain of the receptor tyrosine kinase EphB2. The crystal may be useful for modeling and/or synthesizing mimetics of a binding pocket or ligands that associate with the binding pocket. Such mimetics or ligands may be capable of acting as modulators of receptor tyrosine kinase receptor activity, and they may be useful for treating, inhibiting, or preventing diseases modulated by such receptors. Methods are also provided for regulating the kinase domain of an RTK by changing a binding pocket of the RTK that regulates the kinase domain from an autoinhibited state to an active state or from an active state to an autoinhibited state.

[0001] A portion of the disclosure of this patent document contains material that is subject to copyright protection. The copyright owner has no objection to the facsimile reproduction by anyone of the patent document or patent disclosure, as it appears in the Patent and Trademark Office patent file or records, but otherwise reserves all copyright rights whatsoever.

FIELD OF THE INVENTION

[0002] The present invention relates to binding pockets of receptor tyrosine kinases (RTKs). The binding pockets may regulate the kinase domain of the receptor tyrosine kinases. In particular, the invention relates to a crystal comprising a binding pocket of a receptor tyrosine kinase that regulates the kinase domain of the receptor tyrosine kinase. The crystal may be useful for modeling and/or synthesizing mimetics of a binding pocket or ligands that associate with the binding pocket. Such mimetics or ligands may be capable of acting as modulators of receptor tyrosine kinase receptor activity, and they may be useful for treating, inhibiting, or preventing diseases modulated by such receptors.

[0003] Methods are also provided for regulating the kinase domain of an RTK by changing a binding pocket of the RTK that regulates the kinase domain from an autoinhibited state to an active state or from an active state to an autoinhibited state.

BACKGROUND

[0004] Cell surface receptors with protein-tyrosine kinase activity mediate the biological effects of many extracellular signaling proteins, and thereby regulate aspects of normal cellular behavior such as growth and differentiation, movement, metabolism and survival (van der Geer and Hunter, 1994). The profound consequences of phosphotyrosine signaling on cellular function are emphasized by the effects of mutations that deregulate receptor tyrosine kinase activity, which are frequently associated with malignant transformation or developmental abnormalities. Under normal circumstances, the activation of receptor tyrosine kinases (RTK) requires binding of the appropriate extracellular ligand, which induces either receptor oligomerization or a spatial re-organization of pre-associated receptor chains (Heldin, 1995; Remy et al., 1999; Schlessinger, 2000). As a result, the receptor undergoes autophosphorylation through an intermolecular reaction, both on tyrosine residues which regulate kinase activity, and on residues within non-catalytic regions of the receptor which form binding sites for cytoplasmic targets with SH2 or PTB domains (Pawson and Scott, 1997; Kuriyan and Cowburn, 1997).

[0005] The catalytic activity of tyrosine kinases is frequently stimulated by autophosphorylation within a region of the kinase domain termed the activation segment (Weinnmaster et al., 1984), and indeed this has been viewed as the principal mechanism through which RTKs are activated (Hubbard and Till, 2000; Hubbard, 1997). Structural analysis of the isolated kinase domains of several receptors has revealed how the activation segment represses kinase activity, and the means by which phosphorylation releases this autoinhibition. In the case of the inactive insulin receptor, Tyr 1162 in the activation segment protrudes into the active site, and the activation segment blocks access to the ATP-binding site (Hubbard et al., 1994). Autophosphorylation of Tyr 1162 and two adjacent tyrosine residues repositions the activation segment, thereby freeing the active site to engage exogenous substrates and reorganizing the residues required for catalysis into a functional conformation (Hubbard, 1997). In contrast, the activation segment of the fibroblast growth factor (FGF) receptor is relatively mobile and the tyrosines which become phosphorylated upon receptor activation do not occupy the active site. However, the C-terminal end of the FGFR1 activation segment appears to block access to substrate (Mohammadi et al., 1996).

[0006] Despite the evident importance of the kinase domain activation segment, it remains possible that other mechanisms are important in regulating RTK activity, which might have been missed through an exclusive focus on the kinase domain itself. In particular, recent biochemical and mutational analysis has suggested that Eph receptors may be regulated through a more complex mechanism, involving the juxtamembrane region (Binns et al., 2000; Zisch et al., 1998; Zisch et al., 2000).

[0007] There is only a single Eph receptor tyrosine kinase encoded by the C. elegans genome (VAB-1) (George et al., 1998; Wang et al., 1999a), but the subfamily has undergone a remarkable expansion during metazoan evolution to include at least 14 mammalian members, which therefore represent the largest class of vertebrate RTKs (Holder and Klein, 1999). These Eph receptors fall into two groups, A and B, based on their ability to bind ligands (ephrins), which are themselves cell surface proteins anchored to the plasma membrane either through a GPI linkage (A-type ephrins) or a transmembrane region (B-type) (Eph Nomenclature Committee, 1997; Gale et al., 1996). Signaling between Eph receptors and ephrins generally involves direct cell-cell interactions (Holland et al., 1996; Bruckner et al., 1997), and frequently results in the repulsion of these cells one from another (Drescher et al., 1995; Wang and Anderson, 1997; Mellitzer et al., 1999). Eph receptors are implicated in morphogenetic cell movements (Wang et al., 1999a; Chin-Sang et al., 1999), in defining cell boundaries in structures such as the rhombomeres of the embryonic hindbrain (Xu et al., 1999), in controlling axon guidance and the establishment of topographic maps in the central nervous system (Nakamoto et al., 1996; Brown et al., 2000), and in determining the trajectories of migrating neural crest cells (Krull et al., 1997). Signaling between ephrin and Eph receptor-expressing cells is also essential for angiogenesis, and in conferring distinct arterial and venous identities to developing blood vessels (Wang et al., 1999b; Adams et al., 1999; Gerety et al., 1999).

[0008] The extracellular region of Eph receptors contains an N-terminal ephrin-binding domain (Labrador et al., 1997), that folds into a jellyroll β-sandwich (Himanen et al., 1998), followed by a cysteine-rich region and two fibronectin type III repeats (Pasquale, 1991; Henkemeyer et al., 1994). A single membrane-spanning sequence is followed by a relatively lengthy juxtamembrane region, an uninterrupted kinase domain, an o-helical sterile alpha motif (SAM) domain implicated in receptor oligomerization (Stapleton et al., 1999; Thanos et al., 1999), and a C-terminal motif capable of binding PDZ domain proteins (Hock et al., 1998; Torres et al., 1998). Activation of receptors such as EphB2 or EphA4 is accompanied by autophosphorylation on multiple residues, most notably on two tyrosines within a highly conserved juxtamembrane motif (YIDPFTYEDP in EphB2) and on a tyrosine within the activation segment of the kinase domain (Holland et al., 1997; Choi and Park, 1999; Ellis et al., 1996; Kalo and Pasquale, 1999; Zisch et al., 1998; Binns et al., 2000). By analogy with other RTKs, it might be expected that autophosphorylation of the activation segment tyrosine would stimulate kinase activity, while the juxtamembrane phosphotyrosine sites would recruit cytoplasmic targets. Indeed, the juxtamembrane phosphotyrosine motifs do bind SH2 domain signaling proteins, including p120-RasGAP, Nck, phosphatidylinositol 3′-kinase, SHEP-1 and Src family kinases among others, which can potentially direct cellular responses to ephrin stimulation (Dodelet et al., 1999; Ellis et al., 1996; Holland et al., 1997; Holland et al., 1998; Zisch et al., 1998).

[0009] Consistent with the possibility that phosphorylation of the conserved juxtamembrane tyrosines is important for signaling, substitution of these residues in EphB2 with phenylalanine abrogates EphB2-mediated growth cone collapse upon stimulation of NG108 neuronal cells with ephrin B1. However, this loss of biological activity is apparently not due solely to a failure to engage SH2-containing targets, since substitution of the juxtamembrane tyrosines in EphB2 and EphA4 with phenylalanine leads to a severe loss of ephrin-induced kinase activity (Binns et al., 2000).

SUMMARY OF THE INVENTION

[0010] Applicants have solved the x-ray crystal structure of an Eph receptor tyrosine kinase domain and juxtamembrane region in an autoinhibited state. The results show that in its unphosphorylated state, the juxtamembrane region adopts a helical structure that distorts the conformation of the small lobe of the kinase domain, thereby disrupting the active site. These results indicate a novel mechanism for the regulation of RTKs.

[0011] Solving the crystal structure has enabled the determination of key structural features of the kinase domain and juxtamembrane region, particularly the shape of binding pockets, or parts thereof, that permit the juxtamembrane region and kinase domain to associate resulting in an autoinhibited state. The crystal structure has also enabled the determination of key structural features in molecules or ligands that interact or associate (e.g. nucleotides, cofactors, inhibitors, and substrates) with the binding pockets.

[0012] Knowledge of the autoinhibited conformation of binding pockets of RTKs that regulate the kinase domain is of significant utility in drug discovery. The association of natural ligands and substrates with the binding pockets of RTKs is the basis of many biological mechanisms. In addition, many drugs exert their effects through association with the binding pockets of RTKs. The associations may occur with all or any parts of a binding pocket. An understanding of the association of a drug with the active and autoinhibited conformations of binding pockets of RTKs, will lead to the design and optimization of drugs having more favorable associations with their target RTKs and thus provide improved biological effects. Therefore, information about the shape and structure of binding pockets of RTKs in their autoinhibited and activated states, is invaluable in designing potential modulators of the receptors for use in treating diseases and conditions associated with or modulated by the receptors.

[0013] The present invention relates to a binding pocket of a receptor tyrosine kinase (RTK). In an aspect of the invention, the binding pocket regulates the kinase domain of the receptor tyrosine kinase or is involved in maintaining an autoinhibited state or active state of an RTK.

[0014] The invention also relates to a crystal comprising a binding pocket of an RTK that regulates the kinase domain of the RTK. The binding pocket may be in an autoinhibited state, or active state. Thus, a binding pocket may be involved in maintaining an autoinhibited state or active state of an RTK.

[0015] In an embodiment, the invention, provides a crystal comprising a juxtamembrane region and/or kinase domain of an RTK, or part thereof. The invention contemplates a crystal formed by a juxtamembrane region and a kinase domain of an RTK in an autoinhibited state or active state.

[0016] The invention also contemplates a crystal comprising a binding pocket of a receptor tyrosine kinase that regulates the kinase domain of the receptor tyrosine kinase in association with a ligand.

[0017] The present invention also contemplates molecules or molecular complexes that comprise all or parts of either one or more binding pockets of the invention, or homologs of these binding pockets that have similar structure and shape.

[0018] The present invention also provides a crystal comprising a binding pocket of an RTK of the invention and at least one ligand. A ligand may be complexed or associated with a binding pocket. Ligands include a nucleotide or analogue or part thereof, a substrate or analogue thereof, a cofactor, and/or heavy metal atom. A ligand may be a modulator of the activity of an RTK.

[0019] In an aspect the invention contemplates a crystal comprising a binding pocket of an RTK of the invention complexed with a nucleotide or analogue thereof from which it is possible to derive structural data for the nucleotide or analogue thereof.

[0020] The shape and structure of a binding pocket may be defined by selected atomic contacts in the pocket. In an embodiment, the binding pocket is defined by one or more atomic interactions or enzyme atomic contacts as set forth in Table 2. Each of the atomic interactions is defined in Table 2 by an atomic contact (more preferably, a specific atom where indicated) on the juxtamembrane region and by an atomic contact (more preferably a specific atom where indicated) on the kinase domain, juxtamembrane region, or ligand.

[0021] An isolated polypeptide comprising a binding pocket with the shape and structure of a binding pocket described herein is also within the scope of the invention.

[0022] The invention also provides a method for preparing a crystal of the invention, preferably a crystal of a binding pocket of an Eph receptor, or a complex of such a binding pocket and a ligand.

[0023] Crystal structures of the invention enable a model to be produced for a binding pocket of the invention, or complexes or parts thereof. The models will provide structural information about the autoinhibited or active state of a binding pocket of a RTK or a ligand and its interactions with a binding pocket. Models may also be produced for ligands. A model and/or the crystal structure of the present invention may be stored on a computer-readable medium.

[0024] The present invention includes a model of a binding pocket of the present invention that substantially represents the structural coordinates specified in Table 3. The invention also includes a model that comprises modifications of the model substantially represented by the structural coordinates specified in Table 3. A modification may represent a binding pocket that is involved in maintaining an autoinhibited state or active state of an RTK or regulates the kinase domain of an RTK. A model is a representation or image that predicts the actual structure of the binding pocket. As such, a model is a tool that can be used to probe the relationship between a binding pocket's structure and function at the atomic level and to design molecules that can modulate the binding site and accordingly RTK activity.

[0025] Thus, the invention provides a model of: (a) a binding pocket of an RTK that is involved in maintaining an autoinhibited state or active state of an RTK or regulates the kinase domain of an RTK; and (b) a modification of the model of (a).

[0026] A method is also provided for producing a model of the invention representing a binding pocket of an RTK that is involved in maintaining an autoinhibited state or active state of an RTK or regulates the kinase domain of an RTK, comprising representing amino acids of the binding pocket at substantially the structural coordinates specified in Table 3.

[0027] A crystal and/or model of the invention may be used in a method of determining the secondary and/or tertiary structures of a polypeptide or binding pocket with incompletely characterised structure. Thus, a method is provided for determining at least a portion of the secondary and/or tertiary structure of molecules or molecular complexes which contain at least some structurally similar features to a binding pocket of the invention. This is achieved by using at least some of the structural coordinates set out in Table 3.

[0028] A crystal of the invention may be useful for designing, modeling, identifying, evaluating, and/or synthesizing mimetics of a binding pocket or ligands that associate with a binding pocket. Such mimetics or ligands may be capable of acting as modulators of receptor tyrosine kinase activity, and they may be useful for treating, inhibiting, or preventing diseases modulated by such receptors.

[0029] Thus, the present invention contemplates a method of identifying a modulator of an RTK comprising the step of applying the structural coordinates of a binding pocket, or atomic interactions, or atomic contacts of a binding pocket, to computationally evaluate a test ligand for its ability to associate with the binding pocket, or part thereof. Use of the structural coordinates of a binding pocket, or atomic interactions, or atomic contacts of a binding pocket to design or identify a modulator is also provided.

[0030] In an embodiment, the invention contemplates a method of identifying a modulator of an RTK comprising determining if a test agent inhibits or potentiates an autoinhibited state or active state of a kinase domain of the RTK.

[0031] The invention further contemplates classes of modulators of RTKs based on the shape and structure of a ligand defined in relation to the molecule's spatial association with a binding pocket of the invention. Generally, a method is provided for designing potential inhibitors of RTKs comprising the step of applying the structural coordinates of a ligand defined in relation to its spatial association with a binding pocket, or a part thereof, to generate a compound that is capable of associating with the binding pocket.

[0032] It will be appreciated that a modulator of an RTK may be identified by generating an actual secondary or three-dimensional model of a binding pocket, synthesizing a compound, and examining the components to find whether the required interaction occurs.

[0033] A potential modulator of an RTK identified by a method of the present invention may be confirmed as a modulator by synthesizing the compound, and testing its effect on the RTK in an assay for that receptor's enzymatic activity. Such assays are known in the art (e.g. phosphorylation assays).

[0034] A modulator of the invention may be converted using customary methods into pharmaceutical compositions. A modulator may be formulated into a pharmaceutical composition containing a modulator either alone or together with other active substances.

[0035] Therefore, the methods of the invention for identifying modulators may comprise one or more of the following additional steps:

[0036] (a) testing whether the modulator is a modulator of the activity of a RTK, preferably testing the activity of the modulator in cellular assays and animal model assays;

[0037] (b) modifying the modulator;

[0038] (c) optionally rerunning steps (a) or (b); and (d) preparing a pharmaceutical composition comprising the modulator.

[0039] Steps (a), (b) (c) and (d) may be carried out in any order, at different points in time, and they need not be sequential.

[0040] Still another aspect of the present invention provides a method of conducting a drug discovery business comprising:

[0041] (a) providing one or more systems employing the atomic interactions, atomic contacts, or structural coordinates of a binding pocket of an RTK, for identifying agents by their ability to inhibit or potentiate the atomic interactions or atomic contacts of a binding pocket; and

[0042] (b) conducting therapeutic profiling of agents identified in step (a), or further analogs thereof, for efficacy and toxicity in animals; and

[0043] (c) formulating a pharmaceutical preparation including one or more agents identified in step (b) as having an acceptable therapeutic profile.

[0044] A further aspect of the present invention provides a method of conducting a drug discovery business comprising:

[0045] (a) providing one or more systems for identifying agents by their ability to inhibit or potentiate an autoinhibited state or active state of a kinase domain of an RTK; and

[0046] (b) conducting therapeutic profiling of agents identified in step (a), or further analogs thereof, for efficacy and toxicity in animals; and

[0047] (c) formulating a pharmaceutical preparation including one or more agents identified in step (b) as having an acceptable therapeutic profile.

[0048] In certain embodiments, the subject methods can also include a step of establishing a distribution system for distributing the pharmaceutical preparation for sale, and may optionally include establishing a sales group for marketing the pharmaceutical preparation.

[0049] Yet another aspect of the invention provides a method of conducting a target discovery business comprising:

[0050] (a) providing one or more systems employing the atomic interactions, atomic contacts, or structural coordinates of a binding pocket of an RTK, for identifying agents by their ability to inhibit or potentiate the atomic interactions or atomic contacts, or providing one or more systems for identifying agents by their ability to inhibit or potentiate an autoinhibited state or active state of a kinase domain of an RTK;

[0051] (b) (optionally) conducting therapeutic profiling of agents identified in step (a) for efficacy and toxicity in animals; and

[0052] (c) licensing, to a third party, the rights for further drug development and/or sales for agents identified in step (a), or analogs thereof.

[0053] Methods are also provided for regulating the kinase domain of an RTK by changing a binding domain or pocket of a RTK that regulates the kinase domain from an autoinhibited state to an active state or from an active state to an autoinhibited state. A binding domain or pocket of a RTK may be changed from an autoinhibited state by altering amino acid residues forming the binding pocket (e.g. introducing mutations) or using a modulator.

[0054] In an aspect the invention provides a method for inhibiting kinase activity of an RTK comprising maintaining the RTK or a binding pocket thereof involved in regulating the kinase domain in an autoinhibited state, or potentiating an autoinhibited state for the RTK or binding pocket thereof involved in regulating the kinase domain. An autoinhibited state may be maintained or potentiated by inhibiting phosphorylation of phosphoregulatory sites of the juxtamembrane segment and/or kinase domain (e.g. activation segment). Inhibition may be accomplished using modulators, or altering the structure of a binding pocket of the RTK comprising the phosphoregulatory sites, to prevent phosphorylation of the sites.

[0055] The invention contemplates a method for altering the stability of an autoinhibited state of an RTK comprising phosphorylating phosphoregulatory sites of a juxtamembrane region of the RTK.

[0056] In an aspect the invention relates to a method for changing an RTK from an autoinhibited state to an active state comprising phosphorylating phosphoregulatory sites of a juxtamembrane region of the RTK.

[0057] In another aspect the invention provides a method for activating kinase activity of an RTK comprising phosphorylating phosphoregulatory sites of a juxtamembrane region and kinase domain (e.g. activation segment) of the RTK involved in maintaining the RTK in an autoinhibited state.

[0058] The invention also contemplates a method of treating or preventing a condition or disease associated with an RTK in a cellular organism, comprising:

[0059] (a) administering a modulator of the invention in an acceptable pharmaceutical preparation; and

[0060] (b) activating or inhibiting the RTK to treat or prevent the disease.

[0061] In an aspect the invention provides a method for treating or preventing a condition or disease involving increased RTK activity comprising maintaining the RTK or a binding pocket thereof involved in regulating the kinase domain of the RTK in an autoinhibited state. An autoinhibited state may be maintained as described herein. In an embodiment the condition or disease is cancer.

[0062] The invention provides for the use of a modulator identified by the methods of the invention in the preparation of a medicament to treat or prevent a disease in a cellular organism. Use of modulators of the invention to manufacture a medicament is also provided.

[0063] These and other aspects of the present invention will become evident upon reference to the following detailed description and Tables, and attached drawings.

DESCRIPTION OF THE DRAWINGS AND TABLES

[0064] The present invention will now be described only by way of example, in which reference will be made to the following Figures:

[0065]FIG. 1. Structure-based sequence alignment of the juxtamembrane segments and kinase domains of murine and human EphB2, murine EphA4 and cAPK, and human IRK, FGFR1, Hck, Kit, PDGFRβ, and Flt3. The secondary structure elements of murine EphB2 are indicated, with the juxtamembrane segment, the N-terminal kinase, the g-loop, and the C-terminal lobe coloured red, green, orange, and blue, respectively. Residues Phe 620 and Tyr 750 and those marked with a star are involved in the juxtamembrane/kinase domain interface. The two juxtamembrane tyrosines (604 and 610) that were mutated to phenylalanine are highlighted in light blue. Additional tyrosines identified by Kalo and Pasquale (1999) as in vivo phosphorylation sites are highlighted in purple. The solid triangle indicates the site of a 16 amino acid insertion in chicken EphB2 resulting from alternate RNA processing (Connor and Pasquale, 1995). For Kit and PDGFRβ, tyrosines highlighted in yellow denote autophosphorylation sites, while sites of activating point mutations and deletions are shaded gray (Tsujimura et al., 1996; Irusta and DiMaio, 1998; Kitayama et al., 1995; Hirota et al., 1998). The locations and regions of duplicated sequence for activating Flt3 mutations are indicated by solid black triangles and underlining (Hayakawa et al, 2000).

[0066]FIG. 2. Overview of the autoinhibited EphB2 structure. (a) Ribbon diagram of the EphB2 crystal structure in complex with AMP-PNP. The juxtamembrane region, N-terminal kinase lobe, C-terminal kinase lobe, and g-loop are coloured red, green, blue and orange, respectively. Phosphoregulatory residues Tyr/Phe 604 and Tyr/Phe 610 are coloured light blue, Tyr667 is coloured purple, and the adenine moiety of AMP-PNP is coloured red. (b) Ribbon representation of EphB2 colored as in (a), rotated 90° about the vertical axis. (c) and (d) The juxtamembrane regions in (a) and (b), respectively, have been magnified to detail the interactions between the juxtamembrane region and helix αC of the N-terminal kinase lobe. Carbon, oxygen, nitrogen and sulfur atoms are shown in yellow, red, blue, and green, respectively. Residues involved in the juxtamembrane/kinase domain interface but not shown include Ala616, Ala621, Leu676, Leu693, and Val696. All ribbon diagrams were prepared with RIBBONS (Carson, 1991b).

[0067]FIG. 3. Comparison of autoinhibited EphB2 RTK with the active insulin receptor kinase. (a) Superposition of EphB2 with active insulin receptor kinase (Protein Data Bank ID code 1ir3). The backbone of the juxtamembrane region of EphB2 is shown in red, with the side chains of Tyr/Phe 604 and Tyr/Phe 610 coloured light blue. The EphB2 kinase domain, g-loop and bound adenine moiety are colored blue, orange and red, respectively. The backbone of active IRK is coloured dark green with its activation segment, g loop, and bound nucleotide shown in purple, pink, and light green respectively. The two receptors were aligned using all elements of the C-terminal lobes except the kinase insert region, the activation segment, helix αJ, and the C-terminal tail (rms fit=1.91 Å). (b) Stereo view of the boxed region in (a), with EphB2 phosphorylation sites shown in purple, other EphB2 side chain atoms coloured as in FIGS. 2c and 2 d and IRK side chains shown in green and pink. (c) Stereo view of the boxed region in A), highlighting the kinase catalytic region. This panel is colored as in (b). (d) Stereo view of boxed region in A) highlighting switch region 1. Inactive IRK (Protein Data Band ID code 1irk), shown in yellow, is also superimposed. All side chains are colored according to their respective backbones. IRK residue labeled Thr776 corresponds to Ser776 in EphB2.

[0068]FIG. 4. Electrostatic surface representation of EphB2. Blue and red regions indicate positive and negative potential, respectively (10 to −10 k_(B)T). Phosphoregulatory residues Tyr/Phe 604 and Tyr/Phe 610 are coloured light blue. The molecular surface of EphB2 is oriented as in FIG. 2a and was generated using GRASP (Nicholls et al., 1991)

[0069]FIG. 5. Comparison of the kinase activities of EphA4 and EphB2 wild-type and mutant proteins. (a) GST-EphA4 proteins were expressed in E. coli, and cell lysates were subjected to immunoblot analysis with anti-pTyr antibody (top panel) and anti-GST antibody (lower panel). (b) Equal quantities of GST-EphA4 proteins bound to glutathione sepharose were assessed for their ability to autophosphorylate and phosphorylate enolase by an in vitro kinase assay (top panel). Immunblot analysis of GST-EphA4 proteins with anti-GST antibody (lower panel). (c) Histogram of the specific activities of EphA4 wild-type and mutant proteins as measured by the spectrophotometric coupling assay at 1 mM S-1 peptide and 0.5 μM EphA4 proteins. The velocities represent the mean of triplicate reactions and have been normalized to the specific activity of wild-type EphA4 (top panel). Coomassie stained SDS-PAGE analysis of EphA4 proteins (lower panel). (d) EphB2 and its mutants were expressed in COS-1 cells and immunoprecipitated. The immunoprecipitates were resolved by SDS-PAGE, immunoblotted with anti-pTyr (top panel) or anti-EphB2 (middle panel) antibodies, and assessed for their ability to autophosphorylate and phosphorylate enolase by an in vitro kinase assay (bottom panel).

[0070]FIG. 6. Schematic diagram highlighting differences between the autoinhibited (left) and active (right) states of the Eph receptor family of tyrosine kinases. The active configuration is based on the crystal structure of active IRK (Protein Data Bank ID code 1ir3). Dashed lines indicate regions of activation segment disorder. The numbering scheme corresponds to murine EphB2.

[0071] The present invention will now be described only by way of example, in which reference will be made to the following Tables:

[0072] Table 1 shows the data collection, structure determination and refinement statistics

[0073] Table 2 shows intermolecular contacts in a binding pocket of the invention.

[0074] Table 3 shows the structural coordinates of the juxtamembrane region and kinase domain of an EphB2 receptor.

[0075] In Table 3, from the left, the second column identifies the atom number; the third identifies the atom type; the fourth identifies the amino acid type; the sixth identifies the residue number; the seventh identifies the x coordinates; the eighth identifies the y coordinates; the ninth identifies the z coordinates; the tenth identifies the occupancy; and the eleventh identifies the temperature factor.

DETAILED DESCRIPTION OF THE INVENTION

[0076] Unless otherwise indicated, all terms used herein have the same meaning as they would to one skilled in the art of the present invention. Practitioners are particularly directed to Current Protocols in Molecular Biology (Ansubel) for definitions and terms of the art.

[0077] In accordance with the present invention there may be employed conventional biochemistry, enzymology, molecular biology, crystallography, bioinformatics, microbiology, and recombinant DNA techniques within the skill of the art. Such techniques are explained fully in the literature. See for example, Sambrook, Fritsch, & Maniatis, Molecular Cloning: A Laboratory Manual, Second Edition (1989) Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y); DNA Cloning: A Practical Approach, Volumes I and II (D. N. Glover ed. 1985); Oligonucleotide Synthesis (M. J. Gait ed. 1984); Nucleic Acid Hybridization B. D. Hames & S. J. Higgins eds. (1985); Transcription and Translation B. D. Hames & S. J. Higgins eds (1984); Animal Cell Culture R. I. Freshney, ed. (1986); Immobilized Cells and enzymes IRL Press, (1986); and B. Perbal, A Practical Guide to Molecular Cloning (1984).

[0078] For ease of reference the murine numbering scheme for EphB2 is employed herein to describe specific amino acid residues in aspects of the invention. However, a person skilled in the art could readily determine the corresponding amino acid residues in other RTKs, more particularly in Eph receptors.

[0079] Receptor Tyrosine Kinases (RTKs)

[0080] The invention generally relates to RTKs. RTKs mediate pathways involving multiple extracellular and intracellular signals, integration and amplification of these signals by second messengers, and the activation of cellular processes including cell proliferation, cell division, cell growth, the cell cycle, cell differentiation, cell migration, axonogenesis, nerve cell interactions, and regeneration. Signaling pathways mediated by receptor tyrosine kinases may be initiated by growth factors binding to specific RTKs on cell surfaces. The binding of a growth factor to its receptor activates RTK signaling pathways. The RTKs have an extracellular N-terminal domain that binds the growth factor and a cytoplasmic C-terminal domain containing a protein tyrosine kinase that is capable of autophosphorylation, and the phosphorylation of other protein substrates. Autophosphorylation takes place within a region of the kinase domain of the RTK termed the “activation segment” (Weinnmaster et al., 1984). The binding of a growth factor to its receptor activates the tyrosine kinase which phosphorylates a variety of signaling molecules thereby initiating signaling pathways that can lead to DNA replication, RNA and protein synthesis, and cell division.

[0081] Receptor tyrosine kinases within the scope of the present invention include but are not limited to epidermal growth factor receptor (EGFR), PDGF receptor, insulin receptor tyrosme kinase (IRK), Met receptor tyrosine kinase, fibroblast growth factor (FGF) receptor, insulin receptor, insulin growth factor (IGF-1) receptor, TrkA receptor, IL-3 receptor, B cell receptor, TIE-1, Tek/Tie2, Flt-1, Flk, VEGFR3, EFGR/Erbb, Erb2/neu, Erb3, Ret, Kit, Alk, Ax1, FGFR1, FGFR2, FGFR3, Hck, cAPK, keratinocyte growth factor (KGF) receptor, and Eph receptors.

[0082] The invention preferably contemplates Eph receptors, more preferably EphB2 receptors.

[0083] The term “Eph receptor” refers to a subfamily of closely related transmembrane receptor tyrosine kinases related to Eph, a receptor named for its expression in an erythropoietin-producing human hepatocellular carcinomas cell line. The receptors contain cell adhesion-like domains on their extracellular surface. The N-terminal extracellular region of all Eph family members contains a domain necessary for ligand binding and specificity, followed by a cysteine-rich domain and two fibronectin type II repeats. The cytoplasmic region has a centrally located tyrosine kinase domain. C-terminal to the catalytic region is a sterile alpha motif (SAM) domain, which forms dimers of oligomers in solution and may contribute to regulation of receptor clustering. Localization of clustering of Eph proteins may also be influenced by PDZ domain effectors which potentially interact with specific C-terminal receptor motifs.

[0084] N-terminal to the kinase domain is the juxtamembrane domain. Two invariant tyrosine residues (tyrosines 596 and 602 of EphA4; tyrosines 604 and 610 of EphB2) in the juxtamembrane domain are embedded in a characteristic and highly conserved ˜10 amino acid sequence motif. These tyrosine residues are major sites for autophosphorylation and they have been found to associate with a number of SH2 domain-containing cytoplasmic proteins such as Ras GTPase-activating protein (RasGAP), the p85 subunit of phosphatidylinositol 3′ kinase, Src family kinases, the adapter protein Nck, and SHEP-1 which binds the R-Ras and Rap1A GTPases. Signaling mediated by such SH2 domain-containing proteins may contribute to the physiological effects of Eph receptor stimulation on cell adhesion and cytoskeletal structures.

[0085] There are currently 14 related vertebrate members of the Eph receptor family including receptors in Caenorhabditis elegans and Drosophila. Eph receptors are activated by ephrins. Ephrins are attached to the plasma membrane either via a glycosylphosphatidylinositol linkage (A class) or a transmembrane sequence (B class). Eph receptors are also divided into A and B classes corresponding to their ligand binding specificities and phylogenetic relationships. Class A receptors generally bind A class ephrins, whereas B class ephrins stimulate B class receptors. However, EphA4 is an exception in that it binds and responds to B as well as A class ephrins.

[0086] The group that includes receptors interacting preferentially with ephrin A proteins is called EphA and includes EphA1 (also known as Eph and Esk), EphA2 (also known as Eck, Myk2, Sek2), EphA3 (also known as Cek4, Mek4, Hek, Tyro4, Hek4), EphA4 (also known as Sek, Sek1, Cek8, Hek8, Tyro1), EphA5 (also known as Ehk1, Bsk, Cek7, Hek7, and Rek7), EphA6 (Ehk2, and Hek12) EphA7 (also known as Mdk1, Hek11, Ehk3, Ebk, Cek11), and EphA8 (also known as Eek, Hek3). The group that includes receptors interacting preferentially with ephrin B proteins is called Eph B and includes EphB1 (also known as Elk Cek6, Net, Hek6), EphB2 (also known as Cek5, Nuk, Erk, Qek5, Tyro5, Sek3, hek5, Drt), EphB3 (also known as Cek10, Hek2, Mdks, Tyro6, and Sek4), EphB4 (also known as Htk, Myk1, Tyrol 1, Mdk2), EphB5 (also known as Cek9, Hek9), and EphB6 (also known as Mep).

[0087] “Ephrin” refers to a class of ligands which are anchored to the cell membrane through a transmembrane domain, and bind to the extracellular domain of an Eph receptor, facilitating dimerization and autophosphorylation of the receptor and autophosphorylation of the ligand. The ephrin-A ligands (GPI-anchored ligands) are ephrin-A (also known as B61, LERK1, EFL-1), ephrin-A2 (also known as LERK6, Elf1, mCek7-L, cElf1), ephrin-A3 (also known as LERK3, Ehk1-L, and EFL-2), ephrin-A4 (also known as LERK4, EFL-4, mLERK4), ephrin-A5 (AL1, LERK7, EFL-5, mAL1, [rLERK7], RAGS). The ephrin-B ligands (transmembrane ligands) are ephrin-B1 (also known as LEKR2, ELK-L, EFL-3, Cek5-L, Stra1, [LERK2]), ephrin-B2 (also known as LERK5, HTK-L, NLERK1, Elf2, Htk-L), and ephrin-B3 (also known as LERK8, ELK-L3, NLERK2, EFL-6, Elf3, [rELK-L3]).

[0088] RTKs may be derivable from a variety of sources, including viruses, bacteria, fungi, plants and animals. In a preferred embodiment an RTK is derivable from a mammal, for example, a human.

[0089] An RTK in the present invention may be a wild type enzyme, or part thereof, or a mutant, variant or homolog of such an enzyme.

[0090] The term “wild type” refers to a polypeptide having a primary amino acid sequence which is identical with the native enzyme (for example, the human enzyme).

[0091] The term “mutant” refers to a polypeptide having a primary amino acid sequence which differs from the wild type sequence by one or more amino acid additions, substitutions or deletions. Preferably, the mutant has at least 90% sequence identity with the wild type sequence. Preferably, the mutant has 20 mutations or less over the whole wild-type sequence. More preferably the mutant has 10 mutations or less, most preferably 5 mutations or less over the whole wild-type sequence.

[0092] The term “variant” refers to a naturally occurring polypeptide which differs from a wild-type sequence. A variant may be found within the same species (i.e. if there is more than one isoform of the enzyme) or may be found within a different species. Preferably the variant has at least 90% sequence identity with the wild type sequence. Preferably, the variant has 20 mutations or less over the whole wild-type sequence. More preferably, the variant has 10 mutations or less, most preferably 5 mutations or less over the whole wild-type sequence.

[0093] The term “part” indicates that the polypeptide comprises a fraction of the wild-type amino acid sequence. It may comprise one or more large contiguous sections of sequence or a plurality of small sections. The “part” may comprise a binding pocket as described herein. The polypeptide may also comprise other elements of sequence, for example, it may be a fusion protein with another protein (such as one which aids isolation or crystallisation of the polypeptide). Preferably the polypeptide comprises at least 50%, more preferably at least 65%, most preferably at least 80% of the wild-type sequence.

[0094] The term “homolog” means a polypeptide having a degree of homology with the wild-type amino acid sequence. The term “homology” refers to a degree of complementarity. There may be partial homology or complete homology. In an embodiment of the invention a RTK is substantially homologous to a wild type enzyme. A sequence that is “substantially homologous” refers to a partially complementary sequence that at least partially inhibits an identical sequence from hybridizing to a target nucleic acid. Inhibition of hybridization of a completely complementary sequence to the target sequence may be examined using a hybridization assay (e.g. Southern or northern blot, solution hybridization, etc.) under conditions of reduced stringency. A sequence that is substantially homologous or a hybridization probe will compete for and inhibit the binding of a completely homologous sequence to the target sequence under conditions of reduced stringency. However, conditions of reduced stringency can be such that non-specific binding is permitted, as reduced stringency conditions require that the binding of two sequences to one another be a specific (i.e., a selective) interaction. The absence of non-specific binding may be tested using a second target sequence which lacks even a partial degree of complementarity (e.g., less than about 30% homology or identity). The substantially homologous sequence or probe will not hybridize to the second non-complementary target sequence in the absence of non-specific binding.

[0095] A sequence of an RTK may have at least 60%, 65%, 70%, 75%, 80%, 85%, 90%, 95%, or 99% identity. The phrase “percent identity” or “% identity” refers to the percentage of sequence similarity found in a comparison of two or more amino acid sequences. Percent identity can be determined electronically using conventional programs, e.g., by using the MEGALIGN program (LASERGENE software package, DNASTAR). The MEGALIGN program can create alignments between two or more amino acid sequences according to different methods, e.g., the Clustal Method. (Higgins, D. G. and P. M. Sharp (1988) Gene 73:237-244.) Gaps of low or of no homology between the two amino acid sequences are not included in determining percentage similarity.

[0096] In the present context, a homologous sequence is taken to include an amino acid sequence which may have at least 75, 85 or 90% identity, preferably at least 95 or 98% identity to the wild-type sequence. The homologs will comprise the same sites (for example, binding pocket) as the subject amino acid sequence.

[0097] A sequence may have deletions, insertions or substitutions of amino acid residues which produce a silent change and result in a functionally equivalent enzyme. Deliberate amino acid substitutions may be made on the basis of similarity in polarity, charge, solubility, hydrophobicity, hydrophilicity, and/or the amphipathic nature of the residues as long as the secondary binding activity of the substance is retained. For example, negatively charged amino acids include aspartic acid and glutamic acid; positively charged amino acids include lysine and arginine; and amino acids with uncharged polar head groups having similar hydrophilicity values include leucine, isoleucine, valine, glycine, alanine, asparagine, glutamine, serine, threonine, phenylalanine, and tyrosine.

[0098] The polypeptide may also have a homologous substitution (substitution and replacement are both used herein to mean the interchange of an existing amino acid residue, with an alternative residue) i.e. like-for-like substitution such as basic for basic, acidic for acidic, polar for polar etc. Non-homologous substitution may also occur i.e. from one class of residue to another or alternatively involving the inclusion of unnatural amino acids such as ornithine (hereinafter referred to as Z), diaminobutyric acid ornithine (hereinafter referred to as B), norleucine ornithine (hereinafter referred to as 0), pyriylalanine, thienylalanine, naphthylalanine and phenylglycine.

[0099] Binding Pocket “Binding pocket” refers to a region or site of a RTK or molecular complex thereof that as a result of its shape, associates with another region of the RTK or with a ligand or a part thereof. A binding pocket may regulate the kinase domain of the RTK. A binding pocket may be involved in maintaining an autoinhibited state or active state of an RTK For example, a binding pocket may comprise part of a juxtamembrane region of an RTK that associates with a kinase domain of the RTK (e.g. strand segment Ex1), a site formed by interacting amino acid residues in the juxtamembrane region (e.g. switch region 2), a site formed by interacting amino acid residues in the juxtamembrane region and kinase domain (switch region 1), or a region responsible for binding a ligand.

[0100] The invention contemplates a binding pocket of an RTK in an autoinhibited state or an active state.

[0101] A “ligand” refers to a compound or entity that associates with a binding pocket including nucleotides or analogues or parts thereof, substrates or analogues or parts thereof, or modulators of RTKs, including inhibitors. A ligand may be designed rationally by using a model according to the present invention.

[0102] In an aspect of the invention a binding pocket comprises one or more of the residues involved in coordination of a nucleotide or analog thereof, in particular the amino acid residues involved in coordinating the sugar and phosphate groups of the nucleotide.

[0103] In an aspect of the invention the binding pocket comprises phosphoregulatory sites of a juxtamembrane region or kinase domain. Phosphoregulatory sites are sites that are autophosphorylated following ligand binding of an RTK and that potentiate binding of cytoplasmic signalling targets such as SH2 or SH3 domain signalling proteins. In a specific aspect the binding pocket comprises invariant tyrosine residues (e.g. tyrosines 596 and 602 of EphA4; tyrosines 604 and 610 of EphB2) within a conserved amino acid sequence (e.g. YIDPFTYEPD in EphB2) in the juxtamembrane region A binding pocket may comprise one or more of the amino acid residues for an Eph receptor crystal identified as numbers 1 through 49 shown in Table 2. In an aspect the binding pocket comprises the atomic contacts of atomic interactions 1 to 24 (juxtamembrane-kinase interactions) or interactions 25 to 49 (juxtamembrane-juxtamembrane interactions) identified in Table 2. In a preferred embodiment the binding pocket comprises atomic interactions or atomic contacts 27, 28, 29, and 38; 39 and 40; or 9, 13, 14, 16, 18, 19, 32, 39, 40, and 42 in Table 2. In an aspect of the invention the binding pocket comprises all of the amino acid residues identified in Table 2.

[0104] A binding pocket may be involved in coordination of a ligand or substrate. For example a binding pocket may be involved in coordination of a nucleotide, or part or analog thereof. Therefore, a binding pocket may comprise two or more of the amino acid residues Phe 709, Met 710 Glu 708, Thr 707, Leu 761, Gly 713, (Lys 661), Ala 659, Ile 691, and (Ser 771) of an RTK structure as described herein, that are capable of associating with or coordinating a nucleotide as described herein.

[0105] The term “binding pocket” (BP) also includes a homolog of the binding pocket or a portion thereof. As used herein, the term “homolog” in reference to a binding pocket refers to a binding pocket or a portion thereof which may have deletions, insertions or substitutions of amino acid residues as long as the binding specificity is retained. In this regard, deliberate amino acid substitutions may be made on the basis of similarity in polarity, charge, solubility, hydrophobicity, hydrophilicity, and/or the amphipathic nature of the residues as long as the binding specificity of the binding pocket is retained.

[0106] As used herein, the term “portion thereof” means the structural coordinates corresponding to a sufficient number of amino acid residues of a binding pocket (or homologs thereof) that are capable of providing an autoinhibited or active state or for associating with a ligand For example, the structural coordinates provided in a crystal structure may contain a subset of the amino acid residues in a binding pocket which may be useful in the modelling and design of compounds that bind to the binding pocket.

[0107] Autoinhbited/Active State

[0108] An RTK or a binding pocket thereof may be in an autoinhibited state or active state. An “autoinhibited state” refers to the state of a RTK or a binding pocket that results in disruption of the activation segment of the kinase domain and effective coordination of bound nucleotide. The autoinhibited state results in perturbed catalytic function of an RTK. An autoinhibited state typically occurs in the absence of phosphorylation of the RTK.

[0109] An “active state” refers to the state of a RTK or a binding pocket that does not result in disruption of the activation segment of the kinase domain and effective coordination of bound nucleotide. In the active state the RTK is catalytically active and the juxtamembrane segment is free to bind to signalling proteins such as SH2 domain containing proteins, including p120-RasGAP, Nck, phosphatidylinositol 3′-kinase, SHEP-1, Src family kinases, and the adapter protein Nck. An active state typically occurs in the presence of phosphorylation of the RTK.

[0110] Crystal

[0111] The invention provides crystal structures. As used herein, the term “crystap” or “crystalline” means a structure (such as a three dimensional (3D) solid aggregate) in which the plane faces intersect at definite angles and in which there is a regular structure (such as internal structure) of the constituent chemical species. Thus, the term “crystal” can include any one of: a solid physical crystal form such as an experimentally prepared crystal, a crystal structure derivable from the crystal (including secondary and/or tertiary and/or quaternary structural elements), a 2D and/or 3D model based on the crystal structure, a representation thereof such as a schematic representation thereof or a diagrammatic representation thereof, or a data set thereof for a computer.

[0112] In one aspect the crystal is usable in X-ray crystallography techniques. Here, the crystals used can withstand exposure to X-ray beams used to produce a diffraction pattern data necessary to solve the X-ray crystallographic structure. A crystal may be characterized as being capable of diffracting x-rays in a pattern defined by one of the crystal forms depicted in Blundel et al 1976, Protein Crystallography, Academic Press.

[0113] A crystal of the invention is generally produced in a laboratory; that is, it is an isolated crystal produced by an individual.

[0114] The invention contemplates a crystal comprising a binding pocket of the invention, in particular a binding pocket that regulates the kinase domain of the receptor tyrosine kinase. The binding pocket may be of an autoinhibited state RTK or an active RTK.

[0115] In an aspect of the invention a crystal is provided that comprises the juxtamembrane region and kinase domain of an RTK. In an embodiment the RTK is an Eph Receptor, preferably an EphB receptor. In a preferred embodiment the crystal comprises the juxtamembrane region and the catalytic domain (amino acid residues 595 to 906) of EphB2. The juxtamembrane region and the catalytic domain may be in an autoinhibited state.

[0116] A crystal of the invention may be characterized by one or more of the following characteristics:

[0117] (a) an N-terminal lobe for binding and coordinating ATP for transfer of an α-phosphate to a substrate, comprising a twisted 5-strand β-sheet (denoted β1 to β5) and a single helix αC; and optionally further characterized by (i) a flexible loop that interacts with the adenine base, ribose sugar and the non-hydrolyzable phosphate groups of ATP which loop is formed by β-strands 1 and 2 and a connecting glycine rich segment (g-loop) and

[0118] (ii) an invariant salt bridge between a lysine side chain in 3 strand 3 and a glutamic acid side chain in helix αC that coordinates the position of the P-phosphate of ATP; and

[0119] (b) a C-terminal lobe comprising two β-strands (β7 and β8) and a series of α-helices (αD to αI which is further characterized by (i) strands β7 and β8 in the cleft region between the N- and C-terminal lobes where they contribute side chains that participate in catalysis and the binding of magnesium for the coordination of ATP phosphate groups, (ii) an activation segment flanked by the sequence Asp-Phe-Gly of sub-domain VII and Pro-Ile-Arg of sub-domain VIII, and (iii) a helix αI adjacent to helix αH.

[0120] A crystal of the invention comprising a juxtamembrane region of an RTK, in particular an Eph receptor, more particularly an EphB receptor, most particularly an EphB2 receptor, may be characterized as comprising a single-turn helix αA⁺ (i.e. a 3/10 helix), and a four-turn helix αB′ from the amino terminus of an extended strand segment Ex1. The crystal may also comprise this juxtamemembrane region in association with interacting amino acid residues on the N- and C-terminal lobes of the RTK. (See FIGS. 2-4, and Table 2.)

[0121] A crystal of the invention may comprise a juxtamembrane strand segment Ex1 comprising amino acid residues Lys 602 to Ile 605 which strand extends along the cleft region between the N-and C-terminal lobes of an RTK. The strand is stabilized by hydrogen bonding interactions involving the amide group of Phe 604 with the carbonyl group of Met 748 and the Gln 684 side chain with the backbone amide and carbonyl groups of Ile 605.

[0122] In a further aspect of the invention a crystal is provided comprising a hydrophobic interface site (referred to herein as switch region 1) comprising side chains of Met 748 and Tyr 750 of the C-terminal kinase lobe; Phe 685 and Ile 681 from helix αC, and Pro 607 from the juxtamembrane helix αA^(t), and the phosphoregulatory site or residue Phe 604 which orients into the site.

[0123] A crystal of the invention may comprise helix aA′ which is more particularly characterized by one or more of the following characteristics:

[0124] (a) it is composed of a single rigid turn initiated by Asp 606 and Pro 607 and terminated by Thr 609;

[0125] (b) it is stabilized by the conformational regidity of Pro 607 and the capping interactions involving Asp 606 and Thr 609 with the free backbone amino group and carbonly groups of Phe 608 and Asp 606.

[0126] A crystal of the invention may comprise helix αB¹ which is more particularly characterized by one or more of the following characteristics:

[0127] (a) it is initiated by an Asp Pro sequence (residues 612 and 613); and

[0128] (b) Asp 612 makes capping interactions with the backbone amino and side chain of Asn 614.

[0129] A crystal of the invention may comprise helices αA′ and αB′ of a juxtamembrane region of an RTK and the portion of the N-terminal lobe of the kinase domain centering on helix αC of the RTK which forms an interface with helices αA′ and αB′ and is further characterized as follows:

[0130] (a) hydrophobic side chains projecting from αA′ and αB′ include Pro 607, Phe 608, Pro 613, Val 617, Phe620 and Ala 621 which residues associate intimately with the side chains of Arg 673, Leu 676, and Ile 681 from helix αC and the side chains of Leu 693 and Val 696 from 1-strand 4;

[0131] (b) a hydrogen bond interaction (2.9 Å) between Asn 614 and Arg 672; and

[0132] (c) the small side chains at positions 616 (Ala), 677 (Ser) and 680 (Ser) facilitate the close packing of helices αA′, αB′ and αC.

[0133] A crystal of the invention may comprise a hydrophobic interface site (also referred to herein as “switch region 2”) formed by association of helix αC, strand Ex1 and helices αA′ and αB′ of the juxtamembrane region of an RTK. The interface is characterized as follows:

[0134] (a) projection of the side chain of the phosphoregulatory residue Tyr/Phe 610 onto the surface of the site;

[0135] (b) composed of the side chains of Ile 605 from strand Ex1 and the side chains of Ala 616 and Phe 620 from helix αB′; and

[0136] (c) an electrostatic environment dominated by Asp 606, Glu 611, Asp 612, Glu 615, and Glu 619.

[0137] A crystal of the invention may comprise the following amino acids residues:

[0138] (a) Arg 672, Phe Arg 672, Phe 675, and Leu 676 from helix αC, Tyr 667 from the 13/αC linker and Leu 663, Val 696, Thr 698, Val 703, and Ile 705; or

[0139] (b) Met 748, Tyr 750, Phe 685, Ile 681, Pro 607, and Phe 604; or

[0140] (c) Phe 709, Met 710, Glu 708, Thr 707, Leu 761, Gly 713, Ala 659, Ile 691, Lys 661, and Ser 771; or

[0141] (d) Asp 606, Pro 607, Thr 609, Phe 608 and Asp 606; or

[0142] (e) Asp 612, Pro 613, Asp 612, and Asn 614; or

[0143] (f) Pro 607, Phe 608, Pro 613, Val 617, Phe 620, Als 621, Arg 673, Leu 676, Ile 681, Leu 693, Val 696, Asn 614, Arg 672, Ala 616, Ser 677, and Ser 680; or

[0144] (g) Tyr/Phe 610, Ile 605, Ala 616, Phe 620, Asp 606, Glu 611, Asp 615, and Glu 619.

[0145] Preferably the atoms of the amino acid residues in (a) to (g) have the structural coordinates as set out in Table 3.

[0146] In an embodiment, a crystal of a Eph receptor of the invention belongs to space group P2₁ or P1. The term “space group” refers to the lattice and symmetry of the crystal. In a space group designation the capital letter indicates the lattice type and the other symbols represent symmetry operations that can be carried out on the contents of the asymmetric unit without changing its appearance.

[0147] A crystal of the invention may comprise a unit cell having the following unit dimensions: a=47.05 (±0.05) Å, b=57.62 (±0.05) Å, c=67.74 (±0.05) Å, or a=47.86 (±0.05) Å, b=98.09 (±0.05) Å, c=68.18 (±0.05) Å. The term “unit cell” refers to the smallest and simplest volume element (i.e. parallelpiped-shaped block) of a crystal that is completely representative of the unit of pattern of the crystal. The unit cell axial lengths are represented by a, b, and c. Those of skill in the art understand that a set of atomic coordinates determined by X-ray crystallography is not without standard error.

[0148] In a preferred embodiment, a crystal of the invention has the structural coordinates as shown in Table 3. As used herein, the term “structural coordinates” refers to a set of values that define the position of one or more amino acid residues with reference to a system of axes. The term refers to a data set that defines the three dimensional structure of a molecule or molecules (e.g. Cartesian coordinates, temperature factors, and occupancies). Structural coordinates can be slightly modified and still render nearly identical three dimensional structures. A measure of a unique set of structural coordinates is the root-mean-square deviation of the resulting structure. Structural coordinates that render three dimensional structures (in particular a three dimensional structure of a ligand binding pocket) that deviate from one another by a root-mean-square deviation of less than 5 Å, 4 Å, 3 Å, 2 Å, 1.5 Å. 1.0 Å, or 0.5 Å may be viewed by a person of ordinary skill in the art as very similar.

[0149] Variations in structural coordinates may be generated because of mathematical manipulations of the structural coordinates of a glycosyltransferase described herein. For example, the structural coordinates of Table 3 may be manipulated by crystallographic permutations of the structural coordinates, fractionalization of the structural coordinates, integer additions or substractions to sets of the structural coordinates, inversion of the structural coordinates or any combination of the above.

[0150] Variations in the crystal structure due to mutations, additions, substitutions, and/or deletions of the amino acids, or other changes in any of the components that make up the crystal may also account for modifications in structural coordinates. If such modifications are within an acceptable standard error as compared to the original structural coordinates, the resulting structure may be the same. Therefore, a ligand that bound to a binding pocket of an RTK, in particular an Eph receptor, would also be expected to bind to another binding pocket whose structural coordinates defined a shape that fell within the acceptable error. Such modified structures of a binding pocket thereof are also within the scope of the invention.

[0151] Various computational analyses may be used to determine whether a molecule or the binding pocket thereof is sufficiently similar to all or parts of an RTK or a binding pocket thereof. Such analyses may be carried out using conventional software applications and methods as described herein.

[0152] A crystal of the invention may also be specifically characterised by the parameters, diffraction statistics and/or refinement statistics set out in Tables 1.

[0153] With reference to a crystal of the present invention, residues in a binding pocket may be defined by their spatial proximity to a ligand in the crystal structure. For example, a binding pocket may be defined by its proximity to a nucleotide, substrate molecule, or modulator.

[0154] A crystal of the invention may comprise a binding pocket that is involved in coordination of a nucleotide, or part or analog thereof. Therefore, a crystal may comprise a binding pocket comprising two or more of the amino acid residues Phe 709, Met 710 Glu 708, Thr 707, Leu 761, Gly 713, (Lys 661), Ala 659, Ile 691, and (Ser 771) of an RTK structure as described herein, that are capable of associating with or coordinating a nucleotide as described herein.

[0155] A crystal or secondary or three-dimensional structure of a binding pocket of an RTK, in particular an EphB2 receptor, may be specifically defined by one or more of the atomic contacts of the atomic interactions identified in Table 2. The atomic interactions in Table 2 are defined therein by an atomic contact (more preferably, a specific atom of an amino acid residue where indicated) on the juxtamembrane region, and an atomic contact (more preferably, a specific atom of an amino acid residue where indicated) on the kinase domain, juxtamembrane region, or ligand. In certain embodiments, a crystal of the invention comprises the atomic contacts of atomic interactions 1 to 24 (juxtamembrane-kinase interactions) or atomic interactions 25 to 49 (juxtamembrane-juxtamembrane interactions) identified in Table 2. In certain particular embodiments a crystal is provided comprising the atomic contacts of atomic interactions 27, 28, 29, and 38; 39 and 40; or 9, 13, 14, 16, 18, 19, 32, 39, 40, and 42.

[0156] Preferably, a crystal is defined by the atoms of the atomic contacts in the binding pocket having the structural coordinates for the atoms listed in Table 3.

[0157] A crystal of the invention includes a binding pocket in association with one or more moieties, including heavy-metal atoms i.e. a derivative crystal, or one or more ligands or molecules i.e. a co-crystal.

[0158] The term “associate”, “association” or “associating” refers to a condition of proximity between a moiety (i.e. chemical entity or compound or portions or fragments thereof), and a binding pocket. The association may be non-covalent i.e. where the juxtaposition is energetically favored by for example, hydrogen-bonding, van der Waals, or electrostatic or hydrophobic interactions, or it may be covalent.

[0159] The term “heavy-metal atoms” refers to an atom that can be used to solve an x-ray crystallography phase problem, including but not limited to a transition element a lanthamide metal, or an actinide metal. Lanthamide metals include elements with atomic numbers between 57 and 71, inclusive. Actinide metals include elements with atomic numbers between 89 and 103, inclusive.

[0160] Multiwavelength anomalous diffraction (MAD) phasing may be used to solve protein structures using selenomethionyl (SeMet) proteins. Therefore, a complex of the invention may comprise a crystalline binding pocket with selenium on the methionine residues of the protein.

[0161] A crystal may comprise a complex between a binding pocket and one or more ligands or molecules. In other words the binding pocket may be associated with one or more ligands or molecules in the crystal. The ligand may be any compound that is capable of stably and specifically associating with the binding pocket. A ligand may, for example, be a modulator of an Eph receptor, or a nucleotide or substrate or analogue thereof.

[0162] In an embodiment of the invention, a binding pocket is in association with a cofactor in the crystal. A “cofactor” refers to a molecule required for RTK enzyme activity and/or stability. For example, the cofactor may be a metal ion, including magnesium and other similar atoms or metals.

[0163] In an embodiment, a crystal of the invention comprises a complex between a binding pocket, and a nucleotide or analogue thereof and/or a substrate or analogue thereof. A “nucleotide” includes ATP, ADP, AMP, or analogues thereof, for example, β,γ-imidoadenosine-5′-triphosphate (AMP-PNP, STI-571, and quercetin. A substrate may be for example, a signalling protein, or another portion of the same RTK (e.g juxtamembrane-kinase domain complex). An analog of a nucleotide or substrate is one which mimics the nucleotide or substrate molecule, binding in the binding pocket, but which is incapable (or has a significantly reduced capacity) to take part in a kinase reaction.

[0164] Therefore, the present invention also provides:

[0165] (a) a crystal comprising a binding pocket of an RTK and a nucleotide or analogue thereof;

[0166] (b) a crystal comprising a binding pocket of an RTK and a substrate or analogue thereof;

[0167] (c) a crystal comprising a binding pocket of an RTK and a nucleotide or analogue thereof, and a substrate or analogue thereof.

[0168] A complex may comprise one or more of the intermolecular interactions identified in Table 2. A structure of a complex of the invention may be defined by selected intermolecular contacts, preferably the structural coordinates of the intermolecular contacts as defined in Table 3.

[0169] A crystal of the invention may enable the determination of structural data for a ligand. In order to be able to derive structural data for a ligand, it is necessary for the molecule to have sufficiently strong electron density to enable a model of the molecule to be built using standard techniques. For example, there should be sufficient electron density to allow a model to be built using XTALVIEW (McRee 1992 J. Mol. Graphics. 10 44-46).

[0170] Illustrations of particular crystals of the invention are shown in FIGS. 2, 3, and 4.

[0171] Method of Making a Crystal

[0172] The present invention also provides a method of making a crystal according to the invention. The crystal may be formed from an aqueous solution comprising a purified polypeptide comprising an RTK, in particular an Eph receptor including a variant, part, homolog, or fragment thereof (e.g. a binding pocket). A method may utilize a purified polypeptide comprising a binding pocket to form a crystal. A method may utilize a purified polypeptide comprising a juxtamembrane region and kinase domain of an RTK, in particular an Eph receptor, preferably an EphB receptor, or more preferably an EphB2 receptor.

[0173] The term “purified” in reference to a polypeptide, does not require absolute purity such as a homogenous preparation rather it represents an indication that the polypeptide is relatively purer than in the natural environment. Generally, a purified polypeptide is substantially free of other proteins, lipids, carbohydrates, or other materials with which it is naturally associated, preferably at a functionally significant level for example at least 85% pure, more preferably at least 95% pure, most preferably at least 99% pure. A skilled artisan can purify a polypeptide comprising using standard techniques for protein purification. A substantially pure polypeptide will yield a single major band on a non-reducing polyacrylamide gel. Purity of the polypeptide can also be determined by amino-terminal amino acid sequence analysis.

[0174] A polypeptide used in the method may be chemically synthesized in whole or in part using techniques that are well-known in the art. Alternatively, methods are well known to the skilled artisan to construct expression vectors containing a native or mutated RTK coding sequence and appropriate transcriptional/translational control signals. These methods include in vitro recombinant DNA techniques, synthetic techniques, and in vivo recombination/genetic recombination. See for example the techniques described in Sambrook et al. (Molecular Cloning: A Laboratory Manual, 2nd Edition, Cold Spring Harbor Laboratory press (1989)), and other laboratory textbooks. (See also Sarker et al, Glycoconjugate J. 7:380, 1990; Sarker et al, Proc. Natl. Acad, Sci. USA 88:234-238, 1991, Sarker et al, Glycoconjugate J. 11: 204-209, 1994; Hull et al, Biochem Biophys Res Commun 176:608, 1991 and Pownall et al, Genomics 12:699-704, 1992).

[0175] Crystals may be grown from an aqueous solution containing the purified polypeptide by a variety of conventional processes. These processes include batch, liquid, bridge, dialysis, vapor diffusion, and hanging drop methods. (See for example, McPherson, 1982 John Wiley, New York; McPherson, 1990, Eur. J. Biochem. 189: 1-23; Webber. 1991, Adv. Protein Chem. 41:1-36). Generally, native crystals of the invention are grown by adding precipitants to the concentrated solution of the polypeptide. The precipitants are added at a concentration just below that necessary to precipitate the protein. Water is removed by controlled evaporation to produce precipitating conditions, which are maintained until crystal growth ceases.

[0176] Derivative crystals of the invention can be obtained by soaking native crystals in a solution containing salts of heavy metal atoms. A complex of the invention can be obtained by soaking a native crystal in a solution containing a compound that binds the polypeptide, or they can be obtained by co-crystallizing the polypeptide in the presence of one or more compounds. In order to obtain co-crystals with a compound which binds deep within the tertiary structure of the polypeptide it is necessary to use the second method.

[0177] In a preferred embodiment, the polypeptide is co-crystallised with a compound which stabilises the polypeptide (e.g. AMP-PNP).

[0178] Once the crystal is grown it can be placed in a glass capillary tube and mounted onto a holding device connected to an X-ray generator and an X-ray detection device. Collection of X-ray diffraction patterns are well documented by those skilled in the art (See for example, Ducruix and Geige, 1992, IRL Press, Oxford, England). A beam of X-rays enter the crystal and diffract from the crystal. An X-ray detection device can be utilized to record the diffraction patterns emanating from the crystal. Suitable devices include the Marr 345 imaging plate detector system with an RU200 rotating anode generator.

[0179] Multiwavelength anomalous diffraction (MAD) phasing using selenomethionyl (SeMet) proteins may be used to determine a crystal of the invention. Thus, the invention contemplates a method for determining a crystal structure of the invention using a selenomethionyl derivative of an RTK, including a variant, part, homolog or fragement thereof.

[0180] Methods for obtaining the three dimensional structure of the crystalline form of a molecule or complex are described herein and known to those skilled in the art (see Ducruix and Geige 1992, IRL Press, Oxford, England). Generally, the x-ray crystal structure is given by the diffraction patterns. Each diffraction pattern reflection is characterized as a vector and the data collected at this stage determines the amplitude of each vector. The phases of the vectors may be determined by the isomorphous replacement method where heavy atoms soaked into the crystal are used as reference points in the X-ray analysis (see for example, Otwinowski, 1991, Daresbury, United Kingdom, 80-86). The phases of the vectors may also be determined by molecular replacement (see for example, Naraza, 1994, Proteins 11:281-296). The amplitudes and phases of vectors from the crystalline form determined in accordance with these methods can be used to analyze other related crystalline polypeptides.

[0181] The unit cell dimensions and symmetry, and vector amplitude and phase information can be used in a Fourier transform function to calculate the electron density in the unit cell i.e. to generate an experimental electron density map. This may be accomplished using the PHASES package (Furey, 1990). Amino acid sequence structures are fit to the experimental electron density map (i.e. model building) using computer programs (e.g. Jones, TA. et al, Acta Crystallogr A47, 100-119, 1991). This structure can also be used to calculate a theoretical electron density map. The theoretical and experimental electron density maps can be compared and the agreement between the maps can be described by a parameter referred to as R-factor. A high degree of overlap in the maps is represented by a low value R-factor. The R-factor can be minimized by using computer programs that refine the structure to achieve agreement between the theoretical and observed electron density map. For example, the XPLOR program, developed by Brunger (1992, Nature 355:472-475) can be used for model refinement A three dimensional structure of the molecule or complex may be described by atoms that fit the theoretical electron density characterized by a minimum R value. Files can be created for the structure that defines each atom by coordinates in three dimensions.

[0182] Model

[0183] A crystal structure of the present invention may be used to make a model of a binding pocket of an RTK, preferably an Eph receptor, more preferably an EphB receptor. A model may, for example, be a structural model or a computer model. A model may represent the secondary, tertiary and/or quaternary structure of the binding pocket. The model itself may be in two or three dimensions. It is possible for a computer model to be in three dimensions despite the constraints imposed by a conventional computer screen, if it is possible to scroll along at least a pair of axes, causing “rotation” of the image.

[0184] As used herein, the term “modelling” includes the quantitative and qualitative analysis of molecular structure and/or function based on atomic structural information and interaction models. The term “modelling” includes conventional numeric-based molecular dynamic and energy minimization models, interactive computer graphic models, modified molecular mechanics models, distance geometry and other structure-based constraint models.

[0185] Preferably, modelling is performed using a computer and may be further optimized using known methods. This is called modelling optimisation.

[0186] An integral step to an approach of the invention for designing modulators (e.g. inhibitors) of a subject receptor involves construction of computer graphics models of the binding pocket of a receptor which can be used to design pharmacophores by rational drug design. For instance, for an inhibitor to interact optimally with the subject binding pocket, it will generally be desirable that it have a shape which is at least partly complimentary to that of a particular binding pocket of the receptor, as for example those binding pockets of the receptor which are involved in recognition of a ligand, regulating the kinase domain, or regulating signal transduction. Additionally, other factors, including electrostatic interactions, hydrogen bonding, hydrophobic interactions, desolvation effects, and cooperative motions of ligand and receptor, all influence the binding effect and should be taken into account in attempts to design bioactive modulators (e.g. inhibitors).

[0187] As described herein, a computer-generated molecular model of the subject receptors can be created. In preferred embodiments, at least the Ca-carbon positions of the RTK sequence of interest are mapped to a particular coordinate pattern, such as the coordinates for a binding pocket of an EphB2 shown in Table 3, by homology modeling, and the structure of the protein and velocities of each atom are calculated at a simulation temperature (T_(o)) at which the docking simulation is to be determined. Typically, such a protocol involves primarily the prediction of side-chain conformations in the modeled protein, while assuming a main-chain trace taken from a tertiary structure such as provided in Table 3 and the Figures. Computer programs for performing energy minimization routines are commonly used to generate molecular models. For example, both the CHARMM (Brooks et al. (1983) J Comput Chem 4:187-217) and AMBER (Weiner et al (1981) J. Comput. Chem. 106: 765) algorithms handle all of the molecular system setup, force field calculation, and analysis (see also, Eisenfield et al. (1991) Am J Physiol 261:C376-386; Lybrand (1991) J Pharm Belg 46:49-54; Froimowitz (1990) Biotechniques 8:640-644; Burbam et al. (1990) Proteins 7:99-111; Pedersen (1985) Environ Health Perspect 61:185-190; and Kini et al. (1991) J Biomol Struct Dyn 9:475-488). At the heart of these programs is a set of subroutines that, given the position of every atom in the model, calculate the total potential energy of the system and the force on each atom. These programs may utilize a starting set of atomic coordinates, such as the coordinates provided in Table 3, the parameters for the various terms of the potential energy function, and a description of the molecular topology (the covalent structure). Common features of such molecular modeling methods include: provisions for handling hydrogen bonds and other constraint forces; the use of periodic boundary conditions; and provisions for occasionally adjusting positions, velocities, or other parameters in order to maintain or change temperature, pressure, volume, forces of constraint, or other externally controlled conditions.

[0188] Most conventional energy minimization methods use the input data described above and the fact that the potential energy function is an explicit, differentiable function of Cartesian coordinates, to calculate the potential energy and its gradient (which gives the force on each atom) for any set of atomic positions. This information can be used to generate a new set of coordinates in an effort to reduce the total potential energy and, by repeating this process over and over, to optimize the molecular structure under a given set of external conditions. These energy minimization methods are routinely applied to molecules similar to the subject RTK proteins as well as nucleic acids, polymers and zeolites.

[0189] In general, energy minimization methods can be carried out for a given temperature, T_(i), which may be different than the docking simulation temperature, T_(o). Upon energy minimization of the molecule at T_(i), coordinates and velocities of all the atoms in the system are computed. Additionally, the normal modes of the system are calculated. It will be appreciated by those skilled in the art that each normal mode is a collective, periodic motion, with all parts of the system moving in phase with each other, and that the motion of the molecule is the superposition of all normal modes. For a given temperature, the mean square amplitude of motion in a particular mode is inversely proportional to the effective force constant for that mode, so that the motion of the molecule will often be dominated by the low frequency vibrations.

[0190] After the molecular model has been energy minimized at T_(i), the system is “heated” or “cooled” to the simulation temperature, T_(o), by carrying out an equilibration run where the velocities of the atoms are scaled in a step-wise manner until the desired temperature, T_(o), is reached. The system is further equilibrated for a specified period of time until certain properties of the system, such as average kinetic energy, remain constant. The coordinates and velocities of each atom are then obtained from the equilibrated system.

[0191] Further energy minimization routines can also be carried out. For example, a second class of methods involves calculating approximate solutions to the constrained EOM for the protein. These methods use an iterative approach to solve for the Lagrange multipliers and, typically, only need a few iterations if the corrections required are small. The most popular method of this type, SHAKE (Ryckaert et al. (1977) J Comput Phys 23:327; and Van Gunsteren et al. (1977) Mol Phys 34:1311) is easy to implement and scales as O(N) as the number of constraints increases. Therefore, the method is applicable to macromolecules such as the RTK proteins of the present invention. An alternative method, RATTLE (Anderson (1983) J Comput Phys 52:24) is based on the velocity version of the Verlet algorithm. Like SHAKE, RATTLE is an iterative algorithm and can be used to energy minimize the model of the subject protein.

[0192] Overlays and super positioning with a three dimensional model of a binding pocket of the invention may be used for modelling optimisation. Additionally alignment and/or modelling can be used as a guide for the placement of mutations on a binding pocket to characterize the nature of the site in the context of a cell.

[0193] The three dimensional structure of a new crystal may be modelled using molecular replacement The term “molecular replacement” refers to a method that involves generating a preliminary model of a molecule or complex whose structural coordinates are unknown, by orienting and positioning a molecule whose structural coordinates are known within the unit cell of the unknown crystal, so as best to account for the observed diffraction pattern of the unknown crystal. Phases can then be calculated from this model and combined with the observed amplitudes to give an approximate Fourier synthesis of the structure whose coordinates are unknown. This, in turn, can be subject to any of the several forms of refinement to provide a final, accurate structure of the unknown crystal. Lattman, E., “Use of the Rotation and Translation Functions”, in Methods in Enzymology, 115, pp. 55-77 (1985); M. G. Rossmann, ed., “The Molecular Replacement Method”, Int. Sci. Rev. Ser., No. 13, Gordon & Breach, New York, (1972).

[0194] Commonly used computer software packages for molecular replacement are X-PLOR (Brunger 1992, Nature 355: 472-475), AMoRE (Navaza, 1994, Acta Crystallogr. A50:157-163), the CCP4 package (Collaborative Computational Project, Number 4, “The CCP4 Suite: Programs for Protein Crystallography”, Acta Cryst., Vol. D50, pp. 760-763, 1994), the MERLOT package (P. M. D. Fitzgerald, J. Appl. Cryst., Vol. 21, pp. 273-278, 1988) and XTALVIEW (McCree et al (1992) J. Mol. Graphics 10: 44-46. It is preferable that the resulting structure not exhibit a root-mean-square deviation of more than 3 Å.

[0195] Molecular replacement computer programs generally involve the following steps: (1) determining the number of molecules in the unit cell and defining the angles between them (self rotation function); (2) rotating the known structure against diffraction data to define the orientation of the molecules in the unit cell (rotation function); (3) translating the known structure in three dimensions to correctly position the molecules in the unit cell (translation function); (4) determining the phases of the X-ray diffraction data and calculating an R-factor calculated from the reference data set and from the new data wherein an R-factor between 30-50% indicates that the orientations of the atoms in the unit cell have been reasonably determined by the method; and (5) optionally, decreasing the R-factor to about 20% by refining the new electron density map using iterative refinement techniques known to those skilled in the art (refinement).

[0196] The quality of the model may be analysed using a program such as PROCHECK or 3D-Profiler [Laskowski et al 1993 J. Appl. Cryst. 26:283-291; Luthy R et al, Nature 356: 83-85, 1992; and Bowie, J. U. et al, Science 253: 164-170, 1991]. Once any irregularities have been resolved, the entire structure may be further refined.

[0197] Other molecular modelling techniques may also be employed in accordance with this invention. See, e.g., Cohen, N. C. et al, “Molecular Modelling Software and Methods for Medicinal Chemistry”, J. Med. Chem., 33, pp. 883-894 (1990). See also, Navia, M. A. and M. A. Murcko, “The Use of Structural Information in Drug Design”, Current Opinions in Structural Biology, 2, pp. 202-210 (1992).

[0198] Using the structural coordinates of crystal provided by the invention, molecular modelling may be used to determine the structural coordinates of a crystalline mutant or homolog of an RTK binding pocket By the same token a crystal of the invention can be used to provide a model of a ligand. Modelling techniques can then be used to approximate the three dimensional structure of ligand derivatives and other components which may be able to mimic the atomic contacts between a ligand and binding pocket.

[0199] Computer Format of Crystals/Models

[0200] Information derivable from a crystal of the present invention (for example the structural coordinates) and/or the model of the present invention may be provided in a computer-readable format Therefore, the invention provides a computer readable medium or a machine readable storage medium which comprises the structural coordinates of a binding pocket of an RTK including all or any parts thereof, or ligands including portions thereof. Such storage medium or storage medium encoded with these data are capable of displaying on a computer screen or similar viewing device, a three-dimensional graphical representation of a molecule or molecular complex which comprises such binding pockets or similarly shaped homologous binding pockets. Thus, the invention also provides computerized representations of the secondary or three-dimensional structures of a binding pocket of the invention, including any electronic, magnetic, or electromagnetic storage forms of the data needed to define the structures such that the data will be computer readable for purposes of display and/or manipulation.

[0201] In an aspect the invention provides a computer for producing a three-dimensional representation of a molecule or molecular complex, wherein said molecule or molecular complex comprises a binding pocket defined by structural coordinates of a binding pocket or structural coordinates of atoms of a ligand, or a three-dimensional representation of a homolog of said molecule or molecular complex, wherein said homolog comprises a binding pocket or ligand that has a root mean square deviation from the backbone atoms not more than 1.5 angstroms wherein said computer comprises:

[0202] (a) a machine-readable data storage medium comprising a data storage material encoded with machine readable data wherein said data comprises the structural coordinates of a binding pocket of an RTK or a ligand according to Table 3;

[0203] (b) a working memory for storing instructions for processing said machine-readable data;

[0204] (c) a central-processing unit coupled to said working memory and to said machine-readable data storage medium for processing said machine readable data into said three-dimensional representation; and

[0205] (d) a display coupled to said central-processing unit for displaying said three-dimensional representation.

[0206] The invention also provides a computer for determining at least a portion of the structural coordinates corresponding to an X-ray diffraction pattern of a molecule or molecular complex wherein said computer comprises:

[0207] (a) a machine-readable data storage medium comprising a data storage material encoded with machine readable data wherein said data comprises the structural coordinates according to Table 3;

[0208] (b) a machine-readable data storage medium comprising a data storage material encoded with machine readable data wherein said data comprises an X-ray diffraction pattern of said molecule or molecular complex;

[0209] (c) a working memory for storing instructions for processing said machine-readable data of (a) and (b);

[0210] (d) a central-processing unit coupled to said working memory and to said machine-readable data storage medium of (a) and (b) for performing a Fourier transform of the machine readable data of (a) and for processing said machine readable data of (b) into structural coordinates; and

[0211] (e) a display coupled to said central-processing unit for displaying said structural coordinates of said molecule or molecular complex.

[0212] Structural Studies

[0213] The present invention also provides a method for determining the secondary and/or tertiary structures of a polypeptide or part thereof by using a crystal, or a model according to the present invention. The polypeptide or part thereof may be any polypeptide or part thereof for which the secondary and or tertiary structure is uncharacterised or incompletely characterised. In a preferred embodiment the polypeptide shares (or is predicted to share) some structural or functional homology to a crystal of the present invention. For example, the polypeptide may show a degree of structural homology over some or all parts of the primary amino acid sequence.

[0214] The polypeptide may be an RTK, preferably an Eph receptor with a different specificity for a nucleotide, or substrate. The polypeptide may be an RTK preferably an Eph receptor which requires a different metal cofactor. Alternatively (or in addition) the polypeptide may be an RTK, preferably an Eph receptor from a different species.

[0215] The polypeptide may be a mutant of a wild-type RTK, in particular an Eph receptor. A mutant may arise naturally, or may be made artificially (for example using molecular biology techniques). The mutant may also not be “made” at all in the conventional sense, but merely tested theoretically using the model of the present invention. A mutant may or may not be functional.

[0216] Thus, using a model of the present invention, the effect of a particular mutation on the overall two and/or three dimensional structure of an RTK, in particular an Eph receptor, the autoinhibited state or active state, and/or the interaction between a binding pocket of the enzyme and a ligand can be investigated.

[0217] Alternatively, the polypeptide may perform an analogous function or be suspected to show a similar catalytic mechanism to an RTK, in particular an Eph receptor.

[0218] The polypeptide may also be the same as the polypeptide of the crystal, but in association with a different ligand (for example, modulator or inhibitor) or cofactor. In this way it is possible to investigate the effect of altering the ligand or compound with which the polypeptide is associated on the structure of the binding pocket.

[0219] Secondary or tertiary structure may be determined by applying the structural coordinates of the crystal or model of the present invention to other data such as an amino acid sequence, X-ray crystallographic diffraction data, or nuclear magnetic resonance (NMR) data. Homology modeling, molecular replacement, and nuclear magnetic resonance methods using these other data sets are described below.

[0220] Homology modeling (also known as comparative modeling or knowledge-based modeling) methods develop a three dimensional model from a polypeptide sequence based on the structures of known proteins (i.e. an RTK, in particular an Eph receptor, of the crystal). The method utilizes a computer model of a crystal of the present invention (the “known structure”), a computer representation of the amino acid sequence of the polypeptide with an unknown structure, and standard computer representations of the structures of amino acids. The method in particular comprises the steps of; (a) identifying structurally conserved and variable regions in the known structure; (b) aligning the amino acid sequences of the known structure and unknown structure (c) generating co-ordinates of main chain atoms and side chain atoms in structurally conserved and variable regions of the unknown structure based on the coordinates of the known structure thereby obtaining a homology model; and (d) refining the homology model to obtain a three dimensional structure for the unknown structure. This method is well known to those skilled in the art (Greer, 1985, Science 228, 1055; Bundell et al 1988, Eur. J. Biochem. 172, 513; Knighton et al., 1992, Science 258:130-135, http://biochem.vtedu/courses/modeling/homology.htn). Computer programs that can be used in homology modelling are Quanta and the Homology module in the Insight II modelling package distributed by Molecular Simulations Inc, or MODELLER (Rockefeller University, www.iucr.ac.uk/sinris-top/logical/prg-modeller.html).

[0221] In step (a) of the homology modelling method, a known structure is examined to identify the structurally conserved regions (SCRs) from which an average structure, or framework, can be constructed for these regions of the protein. Variable regions (VRs), in which known structures may differ in conformation, also must be identified. SCRs generally correspond to the elements of secondary structure, such as alpha-helices and beta-sheets, and to ligand- and substrate-binding sites (e.g. nucleotide binding sites). The VRs usually lie on the surface of the proteins and form the loops where the main chain turns.

[0222] Many methods are available for sequence alignment of known structures and unknown structures. Sequence alignments generally are based on the dynamic programming algorithm of Needleman and Wunsch [J. Mol. Biol. 48: 442-453, 1970]. Current methods include FASTA, Smith-Waterman, and BLASTP, with the BLASTP method differing from the other two in not allowing gaps. Scoring of alignments typically involves construction of a 20×20 matrix in which identical amino acids and those of similar character (i.e., conservative substitutions) may be scored higher than those of different character. Substitution schemes which may be used to score alignments include the scoring matrices PAM (Dayhoff et al., Meth. Enzymol. 91: 524-545, 1983), and BLOSUM (Henikoff and Henikoff, Proc. Nat. Acad. Sci. USA 89: 10915-10919, 1992), and the matrices based on alignments derived from three-dimensional structures including that of Johnson and Overington (JO matrices) (J. Mol. Biol. 233: 716-738,1993).

[0223] Alignment based solely on sequence may be used; however, other structural features also may be taken into account. In Quanta, multiple sequence alignment algorithms are available that may be used when aligning a sequence of the unknown with the known structures. Four scoring systems (i.e. sequence homology, secondary structure homology, residue accessibility homology, CA-CA distance homology) are available, each of which may be evaluated during an alignment so that relative statistical weights may be assigned.

[0224] When generating coordinates for the unknown structure, main chain atoms and side chain atoms, both in SCRs and VRs need to be modelled A variety of approaches known to those skilled in the art may be used to assign co-ordinates to the unknown. In particular, the co-ordinates of the main chain atoms of SCRs will be transferred to the unknown structure. VRs correspond most often to the loops on the surface of the polypeptide and if a loop in the known structure is a good model for the unknown, then the main chain co-ordinates of the known structure may be copied. Side chain coordinates of SCRs and VRs are copied if the residue type in the unknown is identical to or very similar to that in the known structure. For other side chain coordinates, a side chain rotamer library may be used to define the side chain coordinates. When a good model for a loop cannot be found fragment databases may be searched for loops in other proteins that may provide a suitable model for the unknown. If desired, the loop may then be subjected to conformational searching to identify low energy conformers if desired.

[0225] Once a homology model has been generated it is analyzed to determine its correctness. A computer program available to assist in this analysis is the Protein Health module in Quanta which provides a variety of tests. Other programs that provide structure analysis along with output include PROCHECK and 3D-Profiler [Luthy R et al, Nature 356: 83-85, 1992; and Bowie, J. U. et al, Science 253: 164-170, 1991]. Once any irregularities have been resolved, the entire structure may be further refined. Refinement may consist of energy minimization with restraints, especially for the SCRs. Restraints may be gradually removed for subsequent minimizations. Molecular dynamics may also be applied in conjunction with energy minimization.

[0226] Molecular replacement involves applying a known structure to solve the X-ray crystallographic data set of a polypeptide of unknown structure. The method can be used to define the phases describing the X-ray diffraction data of a polypeptide of unknown structure when only the amplitudes are known. Thus in an embodiment of the invention, a method is provided for determining three dimensional structures of polypeptides with unknown structure by applying the structural coordinates of a crystal of the present invention to provide an X-ray crystallographic data set for a polypeptide of unknown structure, and (b) determining a low energy conformation of the resulting structure.

[0227] The structural coordinates of a crystal of the present invention may be applied to nuclear magnetic resonance (NMR) data to determine the three dimensional structures of polypeptides with uncharacterised or incompletely characterised sturcture. (See for example, Wuthrich, 1986, John Wiley and Sons, New York: 176-199; Pflugrath et al., 1986, J. Molecular Biology 189: 383-386; Kline et al., 1986 J. Molecular Biology 189:377-382). While the secondary structure of a polypeptide may often be determined by NMR data, the spatial connections between individual pieces of secondary structure are not as readily determined. The structural coordinates of a polypeptide defined by X-ray crystallography can guide the NMR spectroscopist to an understanding of the spatial interactions between secondary structural elements in a polypeptide of related structure. Information on spatial interactions between secondary structural elements can greatly simplify Nuclear Overhauser Effect (NOE) data from two-dimensional NMR experiments. In addition, applying the structural coordinates after the determination of secondary structure by NMR techniques simplifies the assignment of NOE's relating to particular amino acids in the polypeptide sequence and does not greatly bias the NMR analysis of polypeptide structure.

[0228] In an embodiment, the invention relates to a method of determining three dimensional structures of polypeptides with unknown structures, by applying the structural coordinates of a crystal of the present invention to nuclear magnetic resonance (NMR) data of the unknown structure. This method comprises the steps of: (a) determining the secondary structure of an unknown structure using NMR data; and (b) simplifying the assignment of through-space interactions of amino acids. The term “through-space interactions” defines the orientation of the secondary structural elements in the three dimensional structure and the distances between amino acids from different portions of the amino acid sequence. The term “assigmnent” defines a method of analyzing NMR data and identifying which amino acids give rise to signals in the NMR spectrum.

[0229] Screening Methods

[0230] Another aspect of the present invention is the design and identification of agents that inhibit or potentiate an autoinhibition state or active state of an RTK. The rationale design and identification of agents can be accomplished by utilizing the structural coordinates that define a binding pocket of an RTK.

[0231] The structures described herein, and the structures of other polypeptides determined by homology modeling, molecular replacement, and NMR techniques described herein can also be applied to modulator design and identification methods.

[0232] The invention contemplates molecular models, in particular three-dimensional molecular models of RTK proteins, and their use as templates for the design of agents able to mimic or inhibit ligand activation or autophosphorylation or phoshorylation of the proteins (e.g. modulators). A modulator may inhibit or potentiate an autoinhibited state or alternatively an active state.

[0233] In certain embodiments, the present invention provides a method of screening for a ligand that associates with a binding pocket and/or modulates the function of an Eph receptor by using a crystal or a model according to the present invention. The method may involve investigating whether a test compound is capable of associating with or binding a binding pocket, and/or inhibiting or enhancing interactions of atomic contacts in a binding pocket.

[0234] In accordance with an aspect of the present invention, a method is provided for screening for a ligand capable of binding to a binding pocket, wherein the method comprises using a crystal or model according to the invention.

[0235] In another aspect, the invention relates to a method of screening for a ligand capable of binding to a binding pocket, wherein the binding pocket is defined by the structural coordinates given herein, the method comprising contacting the binding pocket with a test compound and determining if the test compound binds to the binding pocket. The binding pocket may be a binding pocket of an autoinhibited state or an active state. In the case of an autoinhibited state binding pocket the screening method may potentially identify an inhibitor that may disrupt catalytic activity of an RTK, for example, by maintaining the RTK in an autoinhibited state. A disruption of catalytic activity may be useful in the treatment of conditions involving increased RTK activity e.g. cancer.

[0236] In one embodiment, the present invention provides a method of screening for a test compound capable of interacting with one or more key amino acid residues of a binding pocket of an RTK. For example, a test compound that interacts with one or more of Tyr/Phe604, Tyr/Phe 610, Tyr 667, Tyr 744, and Tyr 750 of EphB2 receptor may prevent phosphorylation of one or more of the tyrosines and thereby promote the autoinhibited state of the receptor.

[0237] Another aspect of the invention provides a process comprising the steps of:

[0238] (a) performing a method of screening for a ligand described above;

[0239] (b) identifying one or more ligands capable of binding to a binding pocket; and

[0240] (c) preparing a quantity of said one or more ligands.

[0241] A further aspect of the invention provides a process comprising the steps of;

[0242] (a) performing a method of screening for a ligand as described above;

[0243] (b) identifying one or more ligands capable of binding to a binding pocket; and

[0244] (c) preparing a pharmaceutical composition comprising said one or more ligands.

[0245] Once a test compound capable of interacting with one or more key amino acid residues in a binding pocket of an RTK has been identified, further steps may be carried out either to select and/or modify compounds and/or to modify existing compounds, to modulate the interaction with the key amino acid residues in the binding pocket.

[0246] Yet another aspect of the invention provides a process comprising the steps of;

[0247] (a) performing the method of screening for a ligand as described above;

[0248] (b) identifying one or more ligands capable of binding to a binding pocket;

[0249] (c) modifying said one or more ligands capable of binding to a binding pocket;

[0250] (d) performing said method of screening for a ligand as described above; and

[0251] (e) optionally preparing a pharmaceutical composition comprising said one or more ligands.

[0252] In another aspect of the invention, a method of screening for a test compound is provided comprising screening for test compounds that affect (inhibit or potentiate) a juxtamembrane-juxtamembrane interaction (e.g. interactions 25 to 49 in Table 2) or juxtamembrane-kinase interactions (e.g. interactions 1 to 24 in Table 2) described herein.

[0253] As used herein, the term “test compound” means any compound which is potentially capable of associating with a binding pocket, inhibiting or enhancing interactions of atomic contacts in a binding pocket, and/or inhibiting or potentiating an autoinhibited state or active state of an RTK. If, after testing, it is determined that the test compound does bind to the binding pocket, inhibits or enhances interactions of atomic contacts in a binding pocket, and/or inhibits or potentiates an autoinhibited or active state of an RTK, it is known as a “ligand”.

[0254] The test compound may be designed or obtained from a library of compounds which may comprise peptides, as well as other compounds, such as small organic molecules and particularly new lead compounds. By way of example, the test compound may be a natural substance, a biological macromolecule, or an extract made from biological materials such as bacteria, fungi, or animal particularly mammalian) cells or tissues, an organic or an inorganic molecule, a synthetic test compound, a semi-synthetic test compound, a carbohydrate, a monosaccharide, an oligosaccharide or polysaccharide, a glycolipid, a glycopeptide, a saponin, a heterocyclic compound, a structural or functional mimetic, a peptide, a peptidomimetic, a derivatised test compound, a peptide cleaved from a whole protein, or a peptide synthesised synthetically (such as, by way of example, either using a peptide synthesizer or by recombinant techniques or combinations thereof), a recombinant test compound, a natural or a non-natural test compound, a fusion protein or equivalent thereof and mutants, derivatives or combinations thereof.

[0255] The increasing availability of biomacromolecule structures of potential pharmacophoric molecules that have been solved crystallographically has prompted the development of a variety of direct computational methods for molecular design, in which the steric and electronic properties of substrate binding sites are use to guide the design of potential ligands (Cohen et al. (1990) J. Med. Cam. 33: 883-894; Kuntz et al. (1982) J. Mol. Biol 161: 269-288; DesJarlais (1988) J. Med. Cam. 31: 722-729; Bartlett et al. (1989) (Spec. Publ., Roy. Soc. Chem.) 78: 182-196; Goodford et al. (1985) J. Med. Cam. 28: 849-857; DesJarlais et al. J. Med. Cam. 29: 2149-2153). Directed methods generally fall into two categories: (1) design by analogy in which 3-D structures of known molecules (such as from a crystallographic database) are docked to the receptor structure and scored for goodness-of-fit; and (2) de novo design, in which the ligand model is constructed piece-wise in the receptor. The latter approach, in particular, can facilitate the development of novel molecules, uniquely designed to bind to the subject receptor.

[0256] The test compound may be screened as part of a library or a data base of molecules. Modulators of inactivated/activated states of an RTK or binding pocket thereof may be identified by docking a computer representation of compounds from one or more data base of molecules. Data bases which may be used include ACD (Molecular Designs Limited), NCI (National Cancer Institute), CCDC (Cambridge Crystallographic Data Center), CAST (Chemical Abstract Service), Derwent (Derwent Information Limited), Maybridge (Maybridge Chemical Company Ltd), Aldrich (Aldrich Chemical Company), DOCK University of California in San Francisco), and the Directory of Natural Products (Chapman & Hall). Computer programs such as CONCORD (Tripos Associates) or DB-Converter (Molecular Simulations Limited) can be used to convert a data set represented in two dimensions to one represented in three dimensions.

[0257] Test compounds may tested for their capacity to fit spatially into a binding pocket. As used herein, the term “fits spatially” means that the three-dimensional structure of the test compound is accommodated geometrically in a cavity of a binding pocket. The test compound can then be considered to be a ligand.

[0258] A favourable geometric fit occurs when the surface area of the test compound is in close proximity with the surface area of the cavity of a binding pocket without forming unfavorable interactions. A favourable complementary interaction occurs where the test compound interacts by hydrophobic, aromatic, ionic, dipolar, or hydrogen donating and accepting forces. Unfavourable interactions may be steric hindrance between atoms in the test compound and atoms in the binding pocket.

[0259] If a model of the present invention is a computer model, the test compounds may be positioned in a binding pocket through computational docking. If, on the other hand, the model of the present invention is a structural model, the test compounds may be positioned in the binding pocket by, for example, manual docking.

[0260] As used herein the term “docking” refers to a process of placing a compound in close proximity with a binding pocket, or a process of finding low energy conformations of a test compound/binding pocket complex.

[0261] In an illustrative embodiment, the design of potential RTK, in particular EphB2 ligands begins from the general perspective of shape complimentarity for an active site and substrate specificity subsites of the receptor, and a search algorithm is employed which is capable of scanning a database of small molecules of known three-dimensional structure for candidates which fit geometrically into the target protein site. It is not expected that the molecules found in the shape search will necessarily be leads themselves, since no evaluation of chemical interaction need necessarily be made during the initial search. Rather, it is anticipated that such candidates might act as the framework for further design, providing molecular skeletons to which appropriate atomic replacements can be made. Of course, the chemical complimentarily of these molecules can be evaluated, but it is expected that atom types will be changed to maximize the electrostatic, hydrogen bonding, and hydrophobic interactions with the receptor. Most algorithms of this type provide a method for finding a wide assortment of chemical structures that are complementary to the shape of a binding site of the subject receptor. Each of a set of small molecules from a particular data-base, such as the Cambridge Crystallographic Data Bank (CCDB) (Allen et al. (1973) J. Chem. Doc. 13: 119), is individually docked to the binding pocket or site of an RTK, in particular an EphB2 receptor, in a number of geometrically permissible orientations with use of a docking algorithm. In a preferred embodiment, a set of computer algorithms called DOCK, can be used to characterize the shape of invaginations and grooves that form active sites and recognition surfaces of a subject receptor (Kuntz et al. (1982) J. Mol. Biol 161: 269-288). The program can also search a database of small molecules for templates whose shapes are complementary to particular binding pockets or sites of a receptor (DesJarlais et al. (1988) J Med Chem 31: 722-729). These templates normally require modification to achieve good chemical and electrostatic interactions (DesJarlais et al. (1989) ACS Symp Ser 413: 60-69). However, the program has been shown to position accurately known cofactors for ligands based on shape constraints alone.

[0262] The orientations are evaluated for goodness-of-fit and the best are kept for further examination using molecular mechanics programs, such as AMBER or CHARMM. Such algorithms have previously proven successful in finding a variety of molecules that are complementary in shape to a given binding site of a receptor, and have been shown to have several attractive features. First, such algorithms can retrieve a remarkable diversity of molecular architectures. Second, the best structures have, in previous applications to other proteins, demonstrated impressive shape complementarity over an extended surface area. Third, the overall approach appears to be quite robust with respect to small uncertainties in positioning of the candidate atoms.

[0263] Goodford (1985, J Med Chem 28:849-857) and Boobbyer et al. (1989, J Med Chem 32:1083-1094) have produced a computer program (GRID) which seeks to determine regions of high affinity for different chemical groups (termed probes) on the molecular surface of the binding site. GRID hence provides a tool for suggesting modifications to known ligands that might enhance binding. It may be anticipated that some of the sites discerned by GRID as regions of high affinity correspond to “pharmacophoric patterns” determined inferentially from a series of known ligands. As used herein, a pharmacophoric pattern is a geometric arrangement of features of the anticipated ligand that is believed to be important for binding. Attempts have been made to use pharmacophoric patterns as a search screen for novel ligands (Jakes et al. (1987) J Mol Graph 5:41-48; Brint et al. (1987) J Mol Graph 5:49-56; Jakes et al. (1986) J Mol Graph 4:12-20); however, the constraint of steric and “chemical” fit in the putative (and possibly unknown) receptor binding pocket or site is ignored. Goodsell and Olson (1990, Proteins: Struct Funct Genet 8:195-202) have used the Metropolis (simulated annealing) algorithm to dock a single known ligand into a target protein. They allow torsional flexibility in the ligand and use GRID interaction energy maps as rapid lookup tables for computing approximate interaction energies. Given the large number of degrees of freedom available to the ligand, the Metropolis algorithm is time-consuming and is unsuited to searching a candidate database of a few thousand small molecules.

[0264] Yet a further embodiment of the present invention utilizes a computer algorithm such as CLIX which searches such databases as CCDB for small molecules which can be oriented in a receptor binding pocket or site in a way that is both sterically acceptable and has a high likelihood of achieving favorable chemical interactions between the candidate molecule and the surrounding amino acid residues. The method is based on characterizing a binding pocket in terms of an ensemble of favorable binding positions for different chemical groups and then searching for orientations of the candidate molecules that cause maximum spatial coincidence of individual candidate chemical groups with members of the ensemble. The current availability of computer power dictates that a computer-based search for novel ligands follows a breadth-first strategy. A breadth-first strategy aims to reduce progressively the size of the potential candidate search space by the application of increasingly stringent criteria, as opposed to a depth-first strategy wherein a maximally detailed analysis of one candidate is performed before proceeding to the next. CLIX conforms to this strategy in that its analysis of binding is rudimentary it seeks to satisfy the necessary conditions of steric fit and of having individual groups in “correct” places for bonding, without imposing the sufficient condition that favorable bonding interactions actually occur. A ranked “shortlist” of molecules, in their favored orientations, is produced which can then be examined on a molecule-by-molecule basis, using computer graphics and more sophisticated molecular modeling techniques. CLIX is also capable of suggesting changes to the substituent chemical groups of the candidate molecules that might enhance binding.

[0265] The algorithmic details of CLIX is described in Lawerence et al. (1992) Proteins 12:31-41, and the CLIX algorithm can be summarized as follows. The GRID program is used to determine discrete favorable interaction positions (termed target sites) in the binding pocket or site of the protein for a wide variety of representative chemical groups. For each candidate ligand in the CCDB an exhaustive attempt is made to make coincident, in a spatial sense in the binding site of the protein, a pair of the candidate's substituent chemical groups with a pair of corresponding favorable interaction sites proposed by GRID. All possible combinations of pairs of ligand groups with pairs of GRID sites are considered during this procedure. Upon locating such coincidence, the program rotates the candidate ligand about the two pairs of groups and checks for steric hindrance and coincidence of other candidate atomic groups with appropriate target sites. Particular candidate/orientation combinations that are good geometric fits in the binding site and show sufficient coincidence of atomic groups with GRID sites are retained.

[0266] Consistent with the breadth-first strategy, this approach involves simplifying assumptions. Rigid protein and small molecule geometry is maintained throughout. As a first approximation rigid geometry is acceptable as the energy minimized coordinates of an RTK, in particular an EphB2 deduced structure, as described herein, describe an energy minimum for the molecule, albeit a local one. If the surface residues of the site of interest are not involved in crystal contacts then the crystal configuration of those residues is used merely as a starting point for energy minimization, and potential solution structures for those residues determined. The deduced structure described herein should reasonably mimic the mean solution configuration.

[0267] A further assumption implicit in CLIX is that the potential ligand, when introduced into the binding pocket or site of a receptor, does not induce change in the protein's stereochemistry or partial charge distribution and so alter the basis on which the GRID interaction energy maps were computed. It must also be stressed that the interaction sites predicted by GRID are used in a positional and type sense only, i.e., when a candidate atomic group is placed at a site predicted as favorable by GRID, no check is made to ensure that the bond geometry, the state of protonation, or the partial charge distribution favors a strong interaction between the protein and that group. Such detailed analysis should form part of more advanced modeling of candidates identified in the CLIX shortlist Yet another embodiment of a computer-assisted molecular design method for identifying ligands of a binding pocket of an RTK comprises the de novo synthesis of potential ligands by algorithmic connection of small molecular fragments that will exhibit the desired structural and electrostatic complementarity with an active site or binding pocket of the receptor. The methodology employs a large template set of small molecules with are iteratively pieced together in a model of an RTK active site or binding pocket. Each stage of ligand growth is evaluated according to a molecular mechanics-based energy function, which considers van der Waals and coulombic interactions, internal strain energy of the lengthening ligand, and desolvation of both ligand and receptor. The search space can be managed by use of a data tree which is kept under control by pruning according to the binding criteria In an illustrative embodiment, the search space is limited to consider only amino acids and amino acid analogs as the molecular building blocks. Such a methodology generally employs a large template set of amino acid conformations, though need not be restricted to just the 20 natural amino acids, as it can easily be extended to include other related fragments of interest to the medicinal chemist, e.g. amino acid analogs. The putative ligands that result from this construction method are peptides and peptide-like compounds rather than the small organic molecules that are typically the goal of drug design research. The appeal of the peptide building approach is not that peptides are preferable to organics as potential pharmaceutical agents, but rather that: (1) they can be generated relatively rapidly de novo; (2) their energetics can be studied by well-parameterized force field methods; (3) they are much easier to synthesize than are most organics; and (4) they can be used in a variety of ways, for peptidomimetic ligand design, protein-protein binding studies, and even as shape templates in the more commonly used 3D organic database search approach described above.

[0268] Such a de novo peptide design method has been incorporated in a software package called GROW (Moon et al. (1991) Proteins 11:314-328). In a typical design session, standard interactive graphical modeling methods are employed to define the structural environment in which GROW is to operate. For instance, environment could be an active site binding pocket of an RTK, in particular an EphB2, or it could be a set of features on the protein's surface to which the user wishes to bind a peptide-like molecule. The GROW program then operates to generate a set of potential ligand molecules. Interactive modeling methods then come into play again, for examination of the resulting molecules, and for selection of one or more of them for further refinement.

[0269] To illustrate, GROW operates on an atomic coordinate file generated by the user in the interactive modeling session, such as the coordinates provided in Table 3, or the coordinates of a binding pocket or active site as described in Table 2 and 3 plus a small fragment (e.g., an acetyl group) positioned in the active site to provide a starting point for peptide growth. These are referred to as “site” atoms and “seed” atoms, respectively. A second file provided by the user contains a number of control parameters to guide the peptide growth (Moon et al. (1991) Proteins 11:314-328).

[0270] The operation of the GROW algorithm is conceptually fairly simple. GROW proceeds in an iterative fashion, to systematically attach to the seed fragment each amino acid template in a large preconstructed library of amino acid conformations. When a template has been attached, it is scored for goodness-of-fit to the receptor site or binding pocket, and then the next template in the library is attached to the seed. After all the templates have been tested, only the highest scoring ones are retained for the next level of growth. This procedure is repeated for the second growth level; each library template is attached in turn to each of the bonded seed/amino acid molecules that were retained from the first step, and is then scored. Again, only the best of the bonded seed/dipeptide molecules that result are retained for the third level of growth. The growth of peptides can proceed in the N-to-C direction only, the reverse direction only, or in alternating directions, depending on the initial control specifications supplied by the user. Successive growth levels therefore generate peptides that are lengthened by one residue. The procedure terminates when the user-defined peptide length has been reached, at which point the user can select from the constructed peptides those to be studied further. The resulting data provided by the GROW procedure includes not only residue sequences and scores, but also atomic coordinates of the peptides, related directly to the coordinate system of the receptor site atoms.

[0271] In yet another embodiment, potential pharmacophoric compounds can be determined using a method based on an energy minimization-quenched molecular dynamics algorithm for determining energetically favorable positions of functional groups in the binding pockets of the subject receptor. The method can aid in the design of molecules that incorporate such functional groups by modification of known ligands or de novo construction.

[0272] For example, the multiple copy simultaneous search method (MCSS) described by Miranker et al. (1991) Proteins 11: 29-34 may be employed. To determine and characterize a local minima of a functional group in the forcefield of the protein, multiple copies of selected functional groups are first distributed in a binding pocket of interest on the RTK protein. Energy minimization of these copies by molecular mechanics or quenched dynamics yields the distinct local minima. The neighborhood of these minima can then be explored by a grid search or by constrained minimization. In one embodiment, the MCSS method uses the classical time dependent Hartee (TDH) approximation to simultaneously minimize or quench many identical groups in the forcefield of the protein.

[0273] Implementation of the MCSS algorithm requires a choice of functional groups and a molecular mechanics model for each of them. Groups must be simple enough to be easily characterized and manipulated (3-6 atoms, few or no dihedral degrees of freedom), yet complex enough to approximate the steric and electrostatic interactions that the functional group would have in binding to the pocket or site of interest in the RTK protein. A preferred set is, for example, one in which most organic molecules can be described as a collection of such groups (Patai's Guide to the Chemistry of Functional Groups, ed. S. Patai (New York: John Wiley, and Sons, (1989)). This includes fragments such as acetonitrile, methanol, acetate, methyl ammonium, dimethyl ether, methane, and acetaldehyde.

[0274] Determination of the local energy minima in the binding pocket or site requires that many starting positions be sampled. This can be achieved by distributing, for example, 1,000-5,000 groups at random inside a sphere centered on the binding site; only the space not occupied by the protein needs to be considered. If the interaction energy of a particular group at a certain location with the protein is more positive than a given cut-off (e.g. 5.0 kcal/mole) the group is discarded from that site. Given the set of starting positions, all the fragments are minimized simultaneously by use of the TDH approximation (Elber et al. (1990) J Am Chem Soc 112: 9161-9175). In this method, the forces on each fragment consist of its internal forces and those due to the protein. The essential element of this method is that the interactions between the fragments are omitted and the forces on the protein are normalized to those due to a single fragment. In this way simultaneous minimization or dynamics of any number of functional groups in the field of a single protein can be performed.

[0275] Minimization is performed successively on subsets of, for example 100, of the randomly placed groups. After a certain number of step intervals, such as 1,000 intervals, the results can be examined to eliminate groups converging to the same minimum. This process is repeated until minimization is complete (e.g. RMS gradient of 0.01 kcal/mole/C). Thus the resulting energy minimized set of molecules comprises what amounts to a set of disconnected fragments in three dimensions representing potential pharmacophores.

[0276] The next step then is to connect the pharmacophoric pieces with spacers assembled from small chemical entities (atoms, chains, or ring moieties). In a preferred embodiment, each of the disconnected can be linked in space to generate a single molecule using such computer programs as, for example, NEWLEAD (Tschinke et al. (1993) J Med Chem 36: 3863, 3870). The procedure adopted by NEWLEAD executes the following sequence of commands (1) connect two isolated moieties, (2) retain the intermediate solutions for further processing, (3) repeat the above steps for each of the intermediate solutions until no disconnected units are found, and (4) output the final solutions, each of which is a single molecule. Such a program can use for example, three types of spacers: library spacers, single-atom spacers, and fuse-ring spacers. The library spacers are optimized structures of small molecules such as ethylene, benzene and methylamide. The output produced by programs such as NEWLEAD consist of a set of molecules containing the original fragments now connected by spacers. The atoms belonging to the input fragments maintain their original orientations in space. The molecules are chemically plausible because of the simple makeup of the spacers and functional groups, and energetically acceptable because of the rejection of solutions with van-der Waals radii violations.

[0277] A screening method of the present invention may comprise the following steps:

[0278] (i) generating a computer model of a binding pocket using a crystal according to the invention;

[0279] (ii) docking a computer representation of a test compound with the computer model;

[0280] (iii) analysing the fit of the compound in the binding pocket.

[0281] In an aspect of the invention, a method is provided comprising the following steps:

[0282] (a) docking a computer representation of a structure of a test compound into a computer representation of a binding pocket of an RTK defined in accordance with the invention using a computer program, or by interactively moving the representation of the test compound into the representation of the binding pocket;

[0283] (b) characterizing the geometry and the complementary interactions formed between the atoms of the binding pocket and the compound; optionally

[0284] (c) searching libraries for molecular fragments which can fit into the empty space between the compound and the binding pocket and can be linked to the compound; and

[0285] (d) linking the fragments found in (c) to the compound and evaluating the new modified compound.

[0286] In an embodiment of the invention, a method is provided which comprises the following steps:

[0287] (a) docking a computer representation of a test compound from a computer data base with a computer representation of a selected binding pocket on an RTK defined in accordance with the invention to define a complex;

[0288] (b) determining a conformation of the complex with a favorable fit and favourable complementary interactions; and

[0289] (c) identifying test compounds that best fit the selected binding pocket as potential modulators of the RTK.

[0290] In another embodiment of the invention, a method is provided which comprises docking a computer representation of a selected binding pocket of an RTK defined by the atomic interactions, atomic contacts, or structural coordinates in accordance with the invention to define a complex. In particular a method is provided comprising:

[0291] (a) docking a computer representation of a test compound from a computer database with a computer representation of a selected binding pocket of an RTK defined by the atomic interactions, atomic contacts, or structural coordinates described herein;

[0292] (b) determining a conformation of the complex with a favorable fit and favourable complementary interactions; and

[0293] (c) identifying test compounds that best fit the selected binding pocket as potential modulators of the RTK.

[0294] A model used in a screening method may comprise a binding pocket either alone or in association with one or more ligands and/or cofactors. For example, the model may comprise the binding pocket in association with a nucleotide (or analogue thereof), a substrate (or analogue thereof), and/or modulator.

[0295] If the model comprises an unassociated binding pocket, then the selected site under investigation may be the binding pocket itself. The test compound may, for example, mimic a known ligand (e.g. nucleotide or substrate) for an RTK in order to interact with the binding pocket The selected site may alternatively be another site on the RTK.

[0296] If the model comprises an associated binding pocket, for example a binding pocket in association with a ligand, the selected site may be the binding pocket or a site made up of the binding pocket and the complexed ligand, or a site on the ligand itself. The test compound may be investigated for its capacity to modulate the interaction with the associated molecule.

[0297] The screening methods described herein may be applied to a plurality of test compounds, to identify those that best fit the selected site. The screening methods may be used to identify a modulator that changes an autoinhibited state of an RTK to an active state, or an active state to an autoinhibited state.

[0298] A test compound (or plurality of test compounds) may be selected on the basis of their similarity to a known ligand for an RTK, in particular an Eph receptor. For example, the screening method may comprise the following steps:

[0299] (i) generating a computer model of a binding pocket in complex with a ligand;

[0300] (ii) searching for a test compound with a similar three dimensional structure and/or similar chemical groups as the ligand; and

[0301] (iii) evaluating the fit of the test compound in the binding pocket

[0302] Searching may be carried out using a database of computer representations of potential compounds, using methods known in the art.

[0303] The present invention also provides a method for designing ligands for RTKs. It is well known in the art to use a screening method as described above to identify a test compound with promising fit, but then to use this test compound as a starting point to design a ligand with improved fit to the model. Such techniques are known as “structure-based ligand design” (See Kuntz et al., 1994, Acc. Chem. Res. 27:117; Guida, 1994, Current Opinion in Struc. Biol. 4: 777; and Colman, 1994, Current Opinion in Struc. Biol. 4: 868, for reviews of structure-based drug design and identification; and Kuntz et al 1982, J. Mol. Biol. 162:269; Kuntz et al., 1994, Acc. Chem. Res. 27: 117; Meng et al., 1992, J. Compt. Chem. 13: 505; Bohm, 1994, J. Comp. Aided Molec. Design 8: 623 for methods of structure-based modulator design).

[0304] Examples of computer programs that may be used for structure-based ligand design are CAVEAT (Bartlett et al., 1989, in “Chemical and Biological Problems in Molecular Recognition”, Roberts, S. M. Ley, S. V.; Campbell, N. M. eds; Royal Society of Chemistry: Cambridge, pp 182-196); FLOG (Miller et al., 1994, J. Comp. Aided Molec. Design 8:153); PRO Modulator (Clark et al., 1995 J. Comp. Aided Molec. Design 9:13); MCSS (Miranker and Karplus, 1991, Proteins: Structure, Fuction, and Genetics 8:195); and, GRID (Goodford, 1985, J. Med. Chem. 28:849).

[0305] The method may comprise the following steps:

[0306] (i) docking a model of a test compound with a model of a binding pocket;

[0307] (ii) identifying one or more groups on the test compound which may be modified to improve their fit in the binding pocket;

[0308] (iii) replacing one or more identified groups to produce a modified test compound model; and

[0309] (iv) docking the modified test compound model with the model of the binding pocket.

[0310] Evaluation of fit may comprise the following steps:

[0311] (a) mapping chemical features of a test compound such as by hydrogen bond donors or acceptors, hydrophobic/lipophilic sites, positively ionizable sites, or negatively ionizable sites; and

[0312] (b) adding geometric constraints to selected mapped features.

[0313] The fit of the modified test compound may then be evaluated using the same criteria.

[0314] The chemical modification of a group may either enhance or reduce hydrogen bonding interaction, charge interaction, hydrophobic interaction, Van Der Waals interaction or dipole interaction between the test compound and the key amino acid residue(s) of the binding pocket. Preferably the group modifications involve the addition removal or replacement of substituents onto the test compound such that the substituents are positioned to collide or to bind preferentially with one or more amino acid residues that correspond to the key amino acid residues of the binding pocket.

[0315] If a modified test compound model has an improved fit, then it may bind to a binding pocket and be considered to be a “ligand”. Rational modification of groups may be made with the aid of libraries of molecular fragments which may be screened for their capacity to fit into the available space and to interact with the appropriate atoms. Databases of computer representations of libraries of chemical groups are available commercially, for this purpose.

[0316] The test compound may also be modified “in situ” (i.e. once docked into the potential binding pocket), enabling immediate evaluation of the effect of replacing selected groups. The computer representation of the test compound may be modified by deleting a chemical group or groups, or by adding a chemical group or groups. After each modification to a compound, the atoms of the modified compound and potential binding pocket can be shifted in conformation and the distance between the modulator and the binding pocket atoms may be scored on the basis of geometric fit and favourable complementary interactions between the molecules. This technique is described in detail in Molecular Simulations User Manual, 1995 in LUDI.

[0317] Examples of ligand building and/or searching computer programs include programs in the Molecular Simulations Package (Catalyst), ISIS/HOST, ISIS/BASE, and ISIS/DRAW (Molecular Designs Limited), and UNITY (Tripos Associates).

[0318] The “starting point” for rational ligand design may be a known ligand for the enzyme. For example, in order to identify potential modulators of an RTK, in particular an Eph receptor, a logical approach would be to start with a known ligand (for example a nucleotide or known kinase inhibitors) to produce a molecule which mimics the binding of the ligand. Such a molecule may, for example, act as a competitive inhibitor for the true ligand, or may bind so strongly that the interaction (and inhibition) is effectively irreversible.

[0319] Such a method may comprise the following steps:

[0320] (i) generating a computer model of a binding pocket in complex with a ligand;

[0321] (ii) replacing one or more groups on the ligand model to produce a modified ligand; and

[0322] (iii) evaluating the fit of the modified ligand in the binding pocket.

[0323] The replacement groups could be selected and replaced using a compound construction program which replaces computer representations of chemical groups with groups from a computer database, where the representations of the compounds are defined by structural coordinates.

[0324] In an embodiment, a screening method is provided for identifying a ligand of an RTK, in particular an Eph receptor, comprising the step of using the structural coordinates of a nucleotide or component thereof, defined in relation to its spatial association with a binding pocket of the invention, to generate a compound that is capable of associating with the binding pocket In an embodiment of the invention, a screening method is provided for identifying a ligand of an RTK, in particular an Eph receptor, comprising the step of using the structural coordinates of adenosine adenine, or ATP listed in Table 3 to generate a compound for associating with a binding pocket of RTK, in particular an Eph receptor as described herein. The following steps are employed in a particular method of the invention: (a) generating a computer representation of adenosine adenine, or ATP, defined by its structural coordinates listed in Table 3; (b) searching for molecules in a data base that are structurally or chemically similar to the defined adenosine adenine, or ATP, using a searching computer program, or replacing portions of the adenosine adenine, or ATP with similar chemical structures from a database using a compound building computer program.

[0325] A screening method is provided for identifying a ligand of an RTK, in particular an Eph receptor, comprising the step of using the structural coordinates of a binding pocket comprising a juxtamembrane region or part thereof listed in Table 3 to generate a compound for associating with a kinase domain of an RTK, in particular an Eph receptor. The following steps are employed in a particular method of the invention: (a) generating a computer representation of a binding pocket comprising a juxtamembrane region or part thereof defined by its structural coordinates listed in Table 3; and (b) searching for molecules in a data base that are structurally or chemically similar to the defined binding pocket using a searching computer program, or replacing portions of the binding pocket with structures from a database using a compound building computer program.

[0326] The screening methods of the present invention may be used to identify compounds or entities that associate with a molecule that associates with an RTK, in particular an Eph receptor (for example, a nucleotide).

[0327] Compounds and entities (e.g. ligands) of RTKs, in particular Eph receptors, identified using the above-described methods may be prepared using methods described in standard reference sources utilized by those skilled in the art. For example, organic compounds may be prepared by organic synthetic methods described in references such as March, 1994, Advanced Organic Chemistry: Reactions, Mechanisms, and Structure, New York, McGraw Hill.

[0328] Test compounds and ligands which are identified using a crystal or model of the present invention can be screened in assays such as those well known in the art. Screening may be for example in vitro, in cell culture, and/or in vivo. Biological screening assays preferably centre on activity-based response models, binding assays (which measure how well a compound binds to a binding pocket of a receptor), and bacterial, yeast, and animal cell lines (which measure the biological effect of a compound in a cell). The assays may be automated for high throughput screening in which large numbers of compounds can be tested to identify compounds with the desired activity. The biological assay may also be an assay for the binding activity of a compound that selectively binds to the binding pocket compared to other receptors.

[0329] Ligands/Compounds Identified by Screening Methods

[0330] The present invention provides a ligand or compound identified by a screening method of the present invention. A ligand or compound may have been designed rationally by using a model according to the present invention. A ligand or compound identified using the screening methods of the invention may specifically associate with a target compound, or part thereof (e.g. a binding pocket). In the present invention the target compound may be the RTK (e.g. Eph receptor) or part thereof, or a molecule that is capable of associating with the RTK or part thereof (for example a nucleotide). In an embodiment, the ligand is capable of binding to phosphoregulatory sites of a binding pocket, in particular phosphoregulatory sites of a juxtamembrane region or kinase domain. In another embodiment, the ligand is capable of binding to the activation segment of a kinase domain of an Eph receptor.

[0331] A ligand or compound identified using a screening method of the invention may act as a “modulator”, i.e. a compound which affects the activity of an RTK in particular an Eph receptor. A modulator may reduce, enhance or alter the biological function of an RTK, in particular an Eph receptor. For example a modulator may modulate the capacity of the RTK to autophosphorylate. An alteration in biological function may be characterised by a change in specificity. For example, a modulator may cause the RTK to accept a different nucleotide, to phosphorylate a different amino acid residue, or to work with a different metal cofactor. A modulator may dispose an RTK to favor the autoinhibited state or active state. In order to exert its function, the modulator commonly binds to a binding pocket.

[0332] A “modulator” which is capable of reducing the biological function of the enzyme may also be known as an inhibitor. Preferably an inhibitor reduces or blocks the capacity of the enzyme to autophosphorylate. An inhibitor may promote the autoinhibition state of an RTK. The inhibitor may mimic the binding of a nucleotide or substrate, for example, it may be a nucleotide or substrate analogue. A nucleotide analogue may be designed by considering the interactions between the nucleotide and the RTK (for example, by using information derivable from the crystal of the invention) and specifically altering one or more groups (as described above).

[0333] The present invention also provides a method for modulating the activity of an RTK, in particular an Eph receptor, using a modulator according to the present invention. The invention also provides a method for inhibiting autophosphorylation of an RTK, preferably an Eph receptor, by potentiating the autoinhibition state of an RTK, or inhibiting the active state of the RTK. Inhibition of phosphorylation of an RTK may decrease signaling by the RTK and inhibit cellular processes that may be involved in disease. It would be possible to monitor receptor activity following such treatments by a number of methods known in the art.

[0334] A modulator may be an agonist, partial agonist, partial inverse agonist or antagonist of an RTK.

[0335] As used herein, the term “agonist” means any ligand, which is capable of binding to a binding pocket and which is capable of increasing a proportion of the receptor that is in an active form, resulting in an increased biological response. The term includes partial agonists and inverse agonists.

[0336] As used herein, the term “partial agonist” means an agonist that is unable to evoke the maximal response of a biological system, even at a concentration sufficient to saturate the specific receptors.

[0337] As used herein, the term “partial inverse agonist” is an inverse agonist that evokes a submaximal response to a biological system, even at a concentration sufficient to saturate the specific receptors. At high concentrations, it will diminish the actions of a full inverse agonist.

[0338] As used herein, the term “antagonist” means any agent that reduces the action of another agent, such as an agonist. The antagonist may act at the same site as the agonist (competitive antagonism). The antagonistic action may result from a combination of the substance being antagonised (chemical antagonism) or the production of an opposite effect through a different receptor (functional antagonism or physiological antagonism) or as a consequence of competition for the binding site of an intermediate that links receptor activation to the effect observed (indirect antagonism).

[0339] As used herein, the term “competitive antagonism” refers to the competition between an agonist and an antagonist for a binding pocket of a receptor that occurs when the binding of agonist and antagonist becomes mutually exclusive. This may be because the agonist and antagonist compete for the same binding sites or pockets, or combine with adjacent but overlapping sites. A third possibility is that different sites are involved but that they influence the receptor macromolecules in such a way that agonist and antagonist molecules cannot be bound at the same time. If the agonist and antagonist form only short lived combinations with a binding pocket of a receptor so that equilibrium between agonist, antagonist and receptor is reached during the presence of the agonist, the antagonism will be surmountable over a wide range of concentrations. In contrast, some antagonists, when in close enough proximity to their binding site, may form a stable covalent bond with it and the antagonism becomes insurmountable when no spare receptors remain.

[0340] As mentioned above, an identified ligand or compound may act as a ligand model (for example, a template) for the development of other compounds. A modulator may be a mimetic of a ligand.

[0341] Like the test compound (see above) a modulator may be one or a variety of different sorts of molecule. (See examples herein.) A modulator may be an endogenous physiological compound, or it may be a natural or synthetic compound. The modulators of the present invention may be natural or synthetic. The term “modulator” also refers to a chemically modified ligand or compound.

[0342] The technique suitable for preparing a modulator will depend on its chemical nature. For example, peptides can be synthesized by solid phase techniques (Roberge J Y et al (1995) Science 269: 202-204) and automated synthesis may be achieved, for example, using the ABI 43 1 A Peptide Synthesizer (Perlin Elmer) in accordance with the instructions provided by the manufacturer. Once cleaved from the resin, the peptide may be purified by preparative high performance liquid chromatography (e.g., Creighton (1983) Proteins Structures and Molecular Principles, W H Freeman and Co, New York N.Y.). The composition of the synthetic peptides may be confirmed by amino acid analysis or sequencing (e.g., the Edman degradation procedure; Creighton, supra).

[0343] If a modulator is a nucleotide, or a polypeptide expressable therefrom, it may be synthesized, in whole or in part, using chemical methods well known in the art (see Caruthers M H et al (1980) Nuc Acids Res Symp Ser 215-23, Horn T et al (1980) Nuc Acids Res Symp Ser 225-232), or it may be prepared using recombinant techniques well known in the art.

[0344] Organic compounds may be prepared by organic synthetic methods described in references such as March, 1994, Advanced Organic Chemistry: Reactions, Mechanisms, and Structure, New York, McGraw Hill.

[0345] The invention also relates to classes of modulators of RTKs based on the structure and shape of a nucleotide, or component thereof, or a substrate or component thereof; defined in relation to the nucleotide's or substrate's spatial association with a crystal structure of the invention or part thereof.

[0346] A class of modulators may comprise a compound containing a structure of adenine, adenosine, ribose, pyrophosphate, or ATP, and having one or more, preferably all, of the structural coordinates of adenine, adenosine, ribose, pyrophosphate, or ATP of Table 4. Functional groups in the adenine, adenosine, ribose, pyrophosphate, or ATP modulators may be substituted with, for example, alkyl, alkoxy, hydroxyl, aryl, cycloalkyl, alkenyl, alkynyl, thiol, thioalkyl, thioaryl, amino, or halo, or they may be modified using techniques known in the art.

[0347] Another class of modulators defined by the invention are compounds comprising an adenine triphosphate group having the structural coordinates of adenine triphosphate in the active site binding pocket of an Eph receptor.

[0348] The invention contemplates all optical isomers and racemic forms of the modulators of the invention.

[0349] Pharmaceutical Composition

[0350] The present invention also provides for the use of a modulator according to the invention, in the manufacture of a medicament to treat and/or prevent a disease in a mammalian patient. There is also provided a pharmaceutical composition comprising such a modulator and a method of treating and/or preventing a disease comprising the step of administering such a modulator or pharmaceutical composition to a subject, preferably a mammalian patient.

[0351] The pharmaceutical compositions may be for human or animal usage in human and veterinary medicine and will typically comprise a pharmaceutically acceptable carrier, diluent, excipient, adjuvant or combination thereof.

[0352] Acceptable carriers or diluents for therapeutic use are well known in the pharmaceutical art, and are described, for example, in Remington's Pharmaceutical Sciences, Mack Publishing Co. (A. R1 Gennaro edit. 1985). The choice of pharmaceutical carrier, excipient or diluent can be selected with regard to the intended route of administration and standard pharmaceutical practice. The pharmaceutical compositions may comprise as—or in addition to—the carrier, excipient or diluent any suitable binder(s), lubricant(s), suspending agent(s), coating agent(s), solubilising agent(s).

[0353] Preservatives, stabilizers, dyes and even flavouring agents may be provided in the pharmaceutical composition. Examples of preservatives include sodium benzoate, sorbic acid and esters of p-hydroxybenzoic acid. Antioxidants and suspending agents may also be used.

[0354] The routes for administration (delivery) include, but are not limited to, one or more of: oral (e.g. as a tablet, capsule, or as an ingestable solution), topical, mucosal (e.g. as a nasal spray or aerosol for inhalation), nasal, parenteral (e.g. by an injectable form), gastrointestinal, intraspinal, intraperitoneal, intramuscular, intravenous, intrauterine, intraocular, intradermal, intracranial, intratracheal, intravaginal, intracerebroventricular, intracerebral, subcutaneous, ophthalmic (including intravitreal or intracameral), transdermal, rectal, buccal, vaginal, epidural, sublingual.

[0355] Where the pharmaceutical composition is to be delivered mucosally through the gastrointestinal mucosa, it should be able to remain stable during transit though the gastrointestinal tract; for example, it should be resistant to proteolytic degradation, stable at acid pH and resistant to the detergent effects of bile.

[0356] Where appropriate, the pharmaceutical compositions can be administered by inhalation, in the form of a suppository or pessary, topically in the form of a lotion, gel, hydrogel, solution, cream, ointment or dusting powder, by use of a skin patch, orally in the form of tablets containing excipients such as starch or lactose or chalk, or in capsules or ovules either alone or in admixture with excipients, or in the form of elixirs, solutions or suspensions containing flavouring or colouring agents, or they can be injected parenterally, for example intravenously, intramuscularly or subcutaneously. For parenteral administration, the compositions may be best used in the form of a sterile aqueous solution which may contain other substances, for example enough salts or monosaccharides to make the solution isotonic with blood. The aqueous solutions should be suitably buffered (preferably to a pH of from 3 to 9), if necessary. The preparation of suitable parenteral formulations under sterile conditions is readily accomplished by standard pharmaceutical techniques well-known to those skilled in the art.

[0357] If the agent of the present invention is administered parenterally, then examples of such administration include one or more of intravenously, intra-arterially, intraperitoneally, intrathecally, intraventricularly, intraurethrally, intrastemally, intracranially, intramuscularly or subcutaneously administering the agent; and/or by using infusion techniques.

[0358] For buccal or sublingual administration the compositions may be administered in the form of tablets or lozenges which can be formulated in a conventional manner.

[0359] The tablets may contain excipients such as microcrystalline cellulose, lactose, sodium citrate, calcium carbonate, dibasic calcium phosphate and glycine, disintegrants such as starch (preferably corn, potato or tapioca starch), sodium starch glycollate, croscarmellose sodium and certain complex silicates, and granulation binders such as polyvinylpyrrolidone, hydroxypropylmethylcellulose (HPMC), hydroxypropylcellulose (HPC), sucrose, gelatin and acacia. Additionally, lubricating agents such as magnesium stearate, stearic acid, glyceryl behenate and talc may be included.

[0360] Solid compositions of a similar type may also be employed as fillers in gelatin capsules. Preferred excipients in this regard include lactose, starch, cellulose, milk sugar or high molecular weight polyethylene glycols. For aqueous suspensions and/or elxirs, the agent may be combined with various sweetening or flavouring agents, colouring matter or dyes, with emulsifying and/or suspending agents and with diluents such as water, ethanol, propylene glycol and glycerin, and combinations thereof.

[0361] As indicated, a therapeutic agent (e.g. modulator) of the present invention can be administered intranasally or by inhalation and is conveniently delivered in the form of a dry powder inhaler or an aerosol spray presentation from a pressurised container, pump, spray or nebuliser with the use of a suitable propellant, e.g. dichlorodifluoromethane, trichlorofluoromethane, dichlorotetrafluoroethane, a hydrofluoroalkane such as 1,1,1,2-tetrafluoroethane (HFA 134 μm) or 1,1,1,2,3,3,3-heptafluoropropane (HFA 227EA™), carbon dioxide or other suitable gas. In the case of a pressurised aerosol, the dosage unit may be determined by providing a valve to deliver a metered amount The pressurised container, pump, spray or nebuliser may contain a solution or suspension of the active compound, e.g. using a mixture of ethanol and the propellant as the solvent, which may additionally contain a lubricant, e.g. sorbitan trioleate. Capsules and cartridges (made, for example, from gelatin) for use in an inhaler or insufflator may be formulated to contain a powder mix of the agent and a suitable powder base such as lactose or starch.

[0362] Therapeutic administration of polypeptide modulators may also be accomplished using gene therapy. A nucleic acid including a promoter operatively linked to a heterologous polypeptide may be used to produce high-level expression of the polypeptide in cells transfected with the nucleic acid. DNA or isolated nucleic acids may be introduced into cells of a subject by conventional nucleic acid delivery systems. Suitable delivery systems include liposomes, naked DNA, and receptor-mediated delivery systems, and viral vectors such as retroviruses, herpes viruses, and adenoviruses.

[0363] Applications

[0364] The invention provides a method for inhibiting kinase activity of an RTK comprising maintaining the RTK or a binding pocket thereof involved in regulating the kinase domain in an autoinhibited state, or potentiating an autoinhibited state for the RTK or binding pocket thereof involved in regulating the kinase domain. An autoinhibited state may be maintained or potentiated by inhibiting phosphorylation of phosphoregulatory sites of the juxtamembrane segment and/or kinase domain (e.g. activation segment). Inhibition may be accomplished using modulators, or altering the structure of a binding pocket of the RTK comprising the phosphoregulatory sites, to prevent phosphorylation of the sites.

[0365] The invention contemplates a method for altering the stability of an autoinhibited state of an RTK comprising phosphorylating phosphoregulatory sites of a juxtamembrane region of the RTK.

[0366] In an aspect the invention relates to a method for changing an RTK from an autoinhibited state to an active state comprising phosphorylating phosphoregulatory sites of a juxtamembrane region of the RTK.

[0367] In another aspect the invention provides a method for activating kinase activity of an RTK comprising phosphorylating phosphoregulatory sites of a juxtamembrane region and kinase domain (e.g. activation segment) of the RTK.

[0368] The invention further provides a method of treating a mammal, the method comprising administering to a mammal a modulator or pharmaceutical composition of the present invention.

[0369] In particular, the invention contemplates a method of treating or preventing a condition or disease associated with an RTK in a cellular organism, comprising:

[0370] (c) administering a modulator of the invention in an acceptable pharmaceutical preparation; and

[0371] (d) activating or inhibiting the RTK to treat or prevent the disease.

[0372] In an aspect the invention provides a method for treating or preventing a condition or disease involving increased RTK activity comprising maintaining the RTK or a binding pocket thereof involved in regulating the kinase domain of the RTK in an autoinhibited state. An autoinhibited state may be maintained as described herein. In an embodiment the condition or disease is cancer.

[0373] The invention provides for the use of a modulator identified by the methods of the invention in the preparation of a medicament to treat or prevent a disease in a cellular organism. Use of modulators of the invention to manufacture a medicament is also provided.

[0374] Typically, a physician will determine the actual dosage of a modulator or pharmaceutical composition of the invention that will be most suitable for an individual subject and it will vary with the age, weight and response of the particular patient and severity of the condition. There can, of course, be individual instances where higher or lower dosage ranges are merited.

[0375] The specific dose level and frequency of dosage for any particular patient may be varied and will depend upon a variety of factors including the activity of the specific compound employed, the metabolic stability and length of action of that compound, the age, body weight, general health, sex, diet, mode and time of administration, rate of excretion, drug combination, the severity of the particular condition, and the individual undergoing therapy. By way of example, the pharmaceutical composition of the present invention may be administered in accordance with a regimen of 1 to 10 times per day, such as once or twice per day.

[0376] For oral and parenteral administration to human patients, the daily dosage level of the agent may be in single or divided doses.

[0377] The modulators and compositions of the invention may be useful in the prevention and treatment of conditions involving aberrant RTKs.

[0378] Conditions which may be prevented or treated in accordance with the invention include but are not limited to lymphoproliferative conditions, malignant and pre-malignant conditions, arthritis, inflammation, and autoimmune disorders. Malignant and pre-malignant conditions may include solid tumors, B cell lymphomas, chronic lymphocytic leukemia, chronic myelogenous leukemia, prostate hypertrophy, Hirschsprung disease, glioblastoma, breast and ovarian cancer, adenocarcinoma of the salivary gland, premyelocytic leukemia, prostate cancer, multiple endocrine neoplasia type IIA and IIB, medullary thyroid carcinoma, papillary carcinoma, papillary renal carcinoma, hepatocellular carcinoma, gastrointestinal stromal tumors, sporadic mastocytosis, acute myeloid leukemia, large cell lymphoma or Alk lymphoma, chronic myeloid leukemia, hematological/solid tumors, papillary thyroid carcinoma, stem cell leukemia/lymphoma syndrome, acute myelogenous leukemia, osteosarcoma, multiple myeloma, preneoplastic liver foci, and resistance to chemotherapy. Diseases associated with increased cell survival, or the inhibition of apoptosis, include cancers (e.g. follicular lymphomas, carcinomas with p53 mutations, hormone-dependent tumors such as breast cancer, prostate cancer, Kaposi's sarcoma and ovarian cancer); autoimmune disorders (such as lupus erythematosus and immune-related glomerulonephritis rheumatoid arthritis) and viral infections (such as herpes viruses, pox viruses, and adenoviruses); inflammation, graft vs. host disease, acute graft rejection and chronic graft rejection.

[0379] Eph receptors and ephrins mediate contact-dependent repulsive guidance of migrating cells and axons in culture and in vivo. Many Eph family members are prominently expressed in the developing nervous system, and epbrin stimulation of growing primary axons in vitro results in axonal retraction or repulsion, characterized by a collapse of actin-rich growth cone structures at the leading edge of the cell. Mice bearing homozygous null mutations in EphA8 or in both EphB2 and EphB3 exhibit abnormal migration of axon tracts in the brain. Ephrin-induced retraction of exploratory actin filopodia has also been described in vivo in migrating Eph receptor-expressing neural crest cells.

[0380] The Eph receptors and ephrins have also been implicated in cell sorting and boundary formation. Eph-receptor signaling is able to modulate both cell-cell and cell-substrate attachment. Bidirectional Eph receptor-ephrin signaling is important for the formation of boundaries between rhombomeres of the hind brain. These cellular responses to Eph receptor stimulation indicate that they may regulate signaling events which control cytoskeletal architecture and cell adhesion functions.

[0381] Therefore, modulators of Eph receptors may be used to modulate axonogenesis, nerve cell interactions and regeneration, to treat conditions such as neurodegenerative diseases and conditions involving trauma and injury to the nervous system, for example Alzheimer's disease, Parkinson's disease, Huntington's disease, demylinating diseases, such as multiple sclerosis, amyotrophic lateral sclerosis, bacterial and viral infections of the nervous system, deficiency diseases, such as Wernicke's disease and nutritional polyneuropathy, progressive supranuclear palsy, Shy Drager's syndrome, multistem degeneration and olivo ponto cerebellar atrophy, peripheral nerve damage, trauma and ischemia resulting from stroke.

[0382] Therapeutic efficacy and toxicity of compositions and modulators of the invention may be determined by standard pharmaceutical procedures in cell cultures or with experimental animals, such as by calculating the ED₅₀ (the dose therapeutically effective in 50% of the population) or LD₅₀ (the dose lethal to 50% of the population) statistics. The therapeutic index is the dose ratio of therapeutic to toxic effects and it can be expressed as the ED₅₀/LD₅₀ ratio. Pharmaceutical compositions that exhibit large therapeutic indices are preferred.

[0383] The invention will now be illustrated by the following non-limiting example:

EXAMPLE

[0384] The following methods were used in the investigation described in the example:

[0385] Methods

[0386] Protein Expression and Purification

[0387] Mutagenesis of the juxtamembrane tyrosines (Y604/61° F.) of murine EphB2 was performed using a PCR-based approach. The amplified cDNA sequence, corresponding to the receptor's juxtamembrane region and kinase domain (residues 595-906), was cloned into pGEX-4T-1 (Pharmacia). The glutathione-S transferase (GST)-EphB2 construct was transformed into Escherichia coli B834 cells and the cells grown in minimal media supplemented with selenomethionine, with overnight induction at 15° C., and 0.15 mM IPTG (isopropyl-β-D-thiogalactopyranoside, BioShop). Cells were lysed by homogenization and sonication in 25 mM HEPES (pH 7.5), 50 mM NaCl, 20% glycerol, 2 mM DTT, 2 mM phenyl-methyl sulphonyl fluoride. Purification of the selenomethionyl derivative of EphB2 was performed as previously described (Binns et al., 2000), with the exception that the buffer used for gel filtration (buffer C) was 10 mM HEPES (pH 7.5), 50 mM NaCl, 1 mM DTT.

[0388] Crystallization, Data Collection, and Structure Determination

[0389] Hanging drops containing 1 μl of 12.5 mg/ml protein in buffer C were mixed with equal volumes of reservoir buffer containing 0.1 M HEPES (pH 7.0), 0.2 M magnesium chloride, 10% (w/v) PEG 4000, 10% (v/v) isopropanol, and 15% (v/v) ethylene glycol. Rod-like crystals were obtained overnight at 28° C. after streak seeding with smaller crystals obtained initially. The crystals belong to primitive space group P2₁, (a=47.86 Å, b=98.09 Å, c=68.18 Å, α=γ=90°, β=104.97°), with two molecules of EphB2 in the asymmetric unit. Crystals were flash frozen by immersion in liquid nitrogen. A MAD experiment was performed on a frozen crystal at APS beamline BM 14-D (λ1=0.9790 Å, λ2=0.9788 Å, λ3=0.9770 Å) using a Quantum 4 ADSC CCD detector. Data processing and reduction was carried out with the HKL program suite (Otwinowski and Minor, 1997). The programs SHARP (La Fortelle and Bricogne, 1997) and SnB (Miller et al., 1994) were used in combination to locate and subsequently refine positions for 22 of the possible 30 Se sites. Following density modification with Solomon (Abrahams and Leslie, 1996), a partial model was generated using 0 (Jones et al., 1991) and refined using CNS (Brunger et al., 1998) (R-factors>40%). Consequently, crystals of EphB2 in complex with 2 μM AMP-PNP were grown as described above (space group —P1, a=47.05 Å, b=57.62 Å, c=67.74 Å, α=112.95°, β=103.170, γ=91.58°), with two molecules per asymmetric unit Diffraction data was collected to 1.9 Å at APS beamline BM 14-C (λ=1.00 Å) using a Quantum 4 ADSC CCD detector and processed with the HKL program suite. Molecular replacement solutions were determined with AMoRe (Navaza, 1994; CCP4, 1994), using one monomer of the P2₁-derived model as a search molecule. The two AMoRe solutions, which correspond to the two EphB2 molecules in the asymmetric unit, refined readily in CNS. With minimal modification to the starting model, the model has been refined to a working R value of 24.1% and a free R value of 27.7%. As defined in PROCHECK (Laskowski et al., 1993), 90.8% of protein residues are in the most favored regions of the Ramachandran plot, with none in the disallowed regions. Pertinent statistics for data collection and refinement are shown in Table 1.

[0390] Mutagenesis

[0391] The cDNA sequence of the juxtamembrane region and kinase domain of murine EphA4 (amino acids 591-896), corresponding to residues 599-906 of murine EphB2, was cloned into pGEX-4T-2 (Pharmacia). The murine EphB2 numbering scheme was employed, and the corresponding EphA4 residue numbers are listed in parentheses. Using a PCR-based approach, Tyr 604 (Tyr596) and Tyr 610 (Tyr602) were mutated to phenylalanine. The following site-directed mutants were then generated using this doubly mutated construct: (1) ΔJX_(all); deletion of 599-621 (591-613), (2) ΔJX1; deletion of 599-606 (591-598), (3) ΔJX1+2; deletion of 599-610 (591-602), (4) Pro607Gly (Pro599Gly), (5) Phe608Asp (Phe600Asp), (6) Phe620Asp (Phe612Asp), (7) Ser680Trp (Ser672Trp), (8) ΔJX1+2 plus Phe620Asp, and (9) Tyr604/610 Glu (Tyr596/602Glu). The GST-EphA4 constructs were transformed into E. coli BL21 codon plus cells and grown in LB supplemented with ampicillin, with overnight induction at 15° C., 0.15 mM IPTG. Purification was performed as described for EphB2. The mutations Tyr604Phe, Tyr610Phe, Pro607Gly, Phe620Asp, Ser680Trp, Gln684Trp, deletion of 599-606 (ΔJX1), deletion of 599-610 (ΔJX1+2), and deletion of 600-621 (ΔJX1_(all)) in murine EphB2 were generated by site-directed mutagenesis using overlapping oligonucleotide primers containing the above indicated point mutations or deletions. All mutations were confirmed by DNA sequencing.

[0392] Western Blotting

[0393] GST-EphA4 proteins expressed in E. coli (BL21 codon plus), and EphB2 proteins transiently expressed in COS-1 cells, were harvested as previously described (Binns et al, 2000; Holland et al, 1997). Proteins were resolved using 12% denaturing polyacrylamide gel electrophoresis (PAGE), transferred onto a polyvinylidene difluoride membrane (Millipore), blotted with anti-pTyr (Upstate Biotechnology), anti-GST (Santa Cruz Laboratories), or anti-EphB2 antibodies (Holland et al., 1997), and visualized using enhanced chemiluminescence (ECL Plus; Amersham).

[0394] In Vitro Kinase Reactions

[0395] In vitro kinase reactions using GST fusion EphA4 proteins bound to glutathione sepharose or immunoprecipitated EphB2 proteins transiently expressed in COS-1 cells were performed with 5 μg and 2 μg of acid-denatured enolase, respectively, and 5 μCi of [γ³²P]ATP at room temperature as previously described (Binns et al., 2000).

[0396] Spectrophotometric Coupling Assay

[0397] Kinetic analysis of the bacterial expressed EphA4 proteins was performed using a coupled in vitro spectrophotometric kinase assay where production of ADP is coupled to the oxidation of NADH through pyruvate kinase and lactic dehydrogenase (Barker et al., 1995; Binns et al, 2000). The 100-μl reaction volume contained 1 U lactic dehydrogenase, 1 U pyruvate kinase, 1 mM phosphoenolpyruvate, 0.2 mM NADH, and 0.5 mM ATP (in 20 mM MgCl₂, 0.1 mM DTT, 60 mM HEPES [pH 7.5], 20 μg/mL bovine serum albumin). Wild type and mutant EphA4 activity was measured by monitoring absorbance at 340 nm (Varian UV-Visible spectrophotometer) for 90 minutes at a fixed enzyme concentration (0.5 μM) and 1 mM S-1 synthetic peptide (GEEIYGEFD; amide at carboxy terminus) concentrations. For accuracy, protein concentrations were determined by UV spectrometry at 280 nm using molar extinction coefficients. (Andersson, 1998; Collaborative Computational Project, 1994).

[0398] Results and Discussions

[0399] Structure Determination

[0400] Since the expression of active EphB2 polypeptides in E. coli is toxic, efforts were focused on the catalytically repressed Tyr 604/610 Phe double mutant. For the purposes of discussion, these sites are referred to as Tyr/Phe 604 and Tyr/Phe 610. A cytoplasmic fragment (residues 595 to 906) of the murine EphB2 RTK consisting of the latter half of the juxtamembrane region and the entire catalytic domain was expressed as a GST fusion in E. coli and purified to homogeneity (see Methods). The predicted boundaries of the juxtamembrane region are residues 573-620, while those of the kinase and SAM domains are residues 621-892 and residues 919-994, respectively. Protein crystals of two different space groups were grown and the EphB2 structure was determined using a combination of seleno-methionine multiwavelength anomalous dispersion (SeMet MAD) and molecular replacement (MR) methods (see Methods). The EphB2 crystal structure reported here corresponds to the juxtamembrane-catalytic domain fragment in complex with AMP-PNP (β,γ-imidoadenosine-5′-triphosphate). Overall, the EphB2 structure is well ordered except for the first seven and last six amino acid residues, kinase domain residues 651 to 653 connecting β-strands 2 and 3 of the N-terminal catalytic lobe, and residues 774 to 796 corresponding to the kinase activation segment within the C-terminal lobe. Only the adenine ring of AMP-PNP is ordered in experimental and model based electron density maps, and hence the sugar and phosphate groups have not been modeled. Data collection and refinement statistics are listed in Table 1 and a representative alignment of the EphB2 receptor and other protein kinase family members is provided in FIG. 1.

[0401] Overall Description of the Autoinhibited Structure

[0402] The structure of the catalytic domain of EphB2 conforms to that generally observed for protein kinases, consisting of two lobes, a smaller N-terminal lobe and larger C-terminal lobe (FIGS. 2a,b). Protein kinases are capable of a range of conformations owing to an inherent inter-lobe flexibility that allows for both open and closed conformations. However, the catalytically competent conformation is generally a closed structure in which the two catalytic lobes clamp together to form an interfacial nucleotide binding site and catalytic cleft. Surprisingly, the autoinhibited EphB2 catalytic domain adopts a closed conformation that resembles an ‘active’ state.

[0403] The N-terminal lobe of protein kinases consists minimally of a twisted 5-strand β-sheet (denoted β1 to β5 as first described for the cAMP dependent protein kinase (cAPK) and a single helix αC (Knighton et al., 1991). The N-terminal lobe functions to assist in the binding and coordination of ATP for the productive transfer of the y-phosphate to a substrate oriented by the C-terminal lobe. In this regard, β-strands 1 and 2 and the glycine rich connecting segment (g-loop) form a flexible flap that interacts with the adenine base, ribose sugar and the non-hydrolyzable phosphate groups of ATP. Furthermore, an invariant salt bridge between a lysine side chain (sub-domain 2 in the protein kinase nomenclature of Hanks et al., 1988) in β-strand 3 and a glutamic acid side chain (sub-domain 3) in helix αC coordinates the β-phosphate of ATP. In the EphB2 crystal structure, all N-terminal lobe elements implicated in nucleotide binding are well ordered and adopt a prototypical protein kinase arrangement. However, distortions in helix αC and the g-loop arising from interactions with the juxtamembrane segment are evident.

[0404] The C-terminal lobe of protein kinases consists minimally of two β-strands (β7 and β8) and a series of α-helices (αD to αI). Strands β7 and β8 locate to the cleft region between the N- and C-terminal lobes where they contribute side chains that participate in catalysis and the binding of magnesium for the coordination of ATP phosphate groups. In the EphB2 crystal structure, all lower lobe residues implicated in catalysis and ATP coordination appear optimally oriented (FIG. 3c). The activation segment, which is also located in the large catalytic lobe, is disordered as in several other protein kinase structures in which the activation segment is not phosphorylated (reviewed by Johnson et al., 1996). The remaining C-terminal lobe elements, including α-helices αD to αI, are well ordered and adopt the prototypical protein kinase configuration. Terminating the catalytic domain structure is a short helix αJ.

[0405] The EphB2 juxtamembrane region preceding the catalytic domain is highly ordered and adopts an identical conformation in the four unique environments sampled in the two different crystal forms studied. From the amino-terminus, the conformation consists of an extended strand segment Ex1, a single turn 3/10 helix αA′, and a four-turn helix αB′. These elements associate intimately with helix αC of the N-terminal catalytic lobe and also make limited interactions with the C-terminal lobe. As a consequence of the association of the juxtamembrane segment with the N-terminal kinase lobe, significant curvature is imposed on helix αC. This distortion couples directly to local distortions in other N-terminal lobe elements, most critically the g-loop and the invariant lysine-glutamate salt bridge. Together the N-terminal lobe distortions appear to impinge on catalytic function by adversely affecting the coordination of the sugar and phosphate groups of the bound nucleotide.

[0406] With limited contacts to the lower lobe of the catalytic domain, the juxtamembrane segment also sterically impedes the activation segment from adopting the productive conformation that typifies the active state of protein-serine/threonine and tyrosine kinases. Together, the effects on nucleotide coordination and the activation segment form the basis for autoinhibition of EphB2 by the juxtamembrane segment.

[0407] Depending on the splice variant of EphB2, there are 29-45 juxtamembrane residues between the start of strand Ex1 (Lys 602) and the plasma membrane (Connor and Pasquale, 1995). This relatively lengthy sequence makes it impossible to predict whether the autoinhibited structure observed here would be oriented in a specific fashion with respect to the inner surface of the membrane.

[0408] Detailed Analysis of Juxtamembrane Structure

[0409] The juxtamembrane strand segment Ex1, corresponding to amino acid residues Lys 602 to lie 605, extends along the cleft region between the N- and C-terminal lobes (FIGS. 2c,d). The phosphoregulatory residue Tyr/Phe 604 orients into a solvent-exposed hydrophobic pocket composed of the side chains of Met 748 and Tyr 750 of the C-terminal kinase lobe, Ile 681 and Phe 685 from helix αC and Pro 607 from the juxtamembrane helix αA′. This site has been termed ‘switch region 1’ since Tyr/Phe 604 appears well placed to influence the association of the juxtamembrane region with the catalytic domain. Further stabilizing the interaction of strand Ex1 with the lower catalytic lobe are hydrogen bonds between the amide group of Tyr/Phe 604 and the carbonyl group of Met 748 and between the side chain of Gln 684 and the backbone amide and carbonyl groups of lie 605.

[0410] Helix αA′ is composed of a single rigid turn initiated by an Asp606Pro607 sequence and terminated by Thr 609. This helix appears stabilized by the conformational rigidity of Pro 607 and the capping interactions involving the side chains of Asp 606 and Thr 609 with the free backbone amino group and carbonyl groups of Phe 608 and Asp 606. A short linker and then a three-turn helix αB′, initiated by Asp 612Pro613 and extending to Phe 620, follow helix αA′. Helix αB′ is also initiated by an Asp Pro sequence (residues 612 and 613) and Asp 612 makes similar capping interactions with the backbone amino and side chain of Asn 614. Helices αA′ and αB′ form an interface with the N-terminal lobe of the kinase that centers on helix αC. Hydrophobic side chains projecting from αA′ and αB′ include Pro 607, Phe 608, Pro 613, Val 617, Phe620 and Ala 621. These residues associate intimately with Arg 673, Leu 676, and Ile 681 from helix αC and Leu 693 and Val 696 from α-strand 4. In addition, a hydrogen bond interaction (2.9 Å) is observed between Asn 614 and Arg 672 (FIG. 2c), and the small side chains at positions 616 (Ala), 677 (Ser) and 680 (Ser) facilitate the close packing of helices αA′, αB′ and αC.

[0411] Opposite to, but contiguous with, the site of association with helix αC, strand Ex1 and helices αA′ and αB′ form an interface composed primarily of hydrophobic interactions. The side chain of the phosphoregulatory residue Tyr/Phe 610 projects onto the surface of this site and appears well positioned to exert an influence on the local juxtamembrane structure. This interface, termed ‘switch region 2’, is composed of the side chains of Ile 605 from strand Ex1 and the side chains of Ala 616 and Phe 620 from helix αB′.

[0412] Effect of the Juxtamembrane Engagement on the N-Terminal Lobe Structure

[0413] Comparison of the EphB2 crystal structure with that of the ‘active’ triply phosphorylated insulin receptor tyrosine kinase (active IRK (Hubbard, 1997)) indicates the mechanism by which the juxtamembrane region of EphB2 inhibits the catalytic domain. Superposition of C-terminal kinase lobe elements places the majority of N-terminal lobe elements into close correspondence (FIGS. 3a-d). A distinguishing feature of the EphB2 structure is a 14° kink midway along helix αC centered at Glu 678. This kink, which coincides with the site of association with the juxtamembrane elements Ex1, αA′ and αB′, displaces the forward facing N-terminus of helix αC 6.8 Å upward and outward from the equivalent position observed in IRK (FIGS. 3a,c). Stabilizing this kink internally are side chain/main chain interactions involving Ser 677 and Ser 680.

[0414] The kink in helix αC places its forward projecting terminus in close proximity to β-strands 3, 4, and 5, forming a tighter interface than that observed in active IRK (FIG. 3b). Residues participating in this interface include Arg 672, Phe 675, and Leu 676 from helix αC, Tyr 667 from the β3/αC linker and Leu 663, Val 696, Thr 698, Val 703, and Ile 705 from the β-strands. Interestingly, tyrosine 667, which is centrally positioned within this interface and is highly conserved amongst the Eph receptor family members, has been identified as an in vivo site of phosphorylation (Kalo and Pasquale, 1999), suggesting a possible phosphoregulatory role.

[0415] The close association of helix αC with β-strands 3, 4 and 5 is achieved with a local alteration to the twist of the forward projecting termini of β-strands 1, 2 and 3 that leaves the bulk of the N-terminal sheet structure unperturbed. The g-loop side chain Phe 640 plays a role in coupling the β-strand movements to that of helix αC through a direct interaction with Phe 675. The altered twist of the β1, β2 and β3-strand termini displace main chain atoms at the end of the g-loop (Glu 639 and Phe 640) by approximately 3.3 Å. In addition, together with the kink in helix αC, the altered twist of the β-strands displaces the invariant glutamate and lysine side chains by 2.4 and 2.1 Å, respectively, relative to their positions in active IRK (FIG. 3c). As a consequence, the ability of the catalytic domain to coordinate the sugar and phosphate groups of bound nucleotide is compromised (FIGS. 3a-c). Since the domain closure and the bulk of the N-terminal β-sheet structure is not perturbed, the adenine binding pocket is well formed and indeed the adenine base of bound AMP-PNP is ordered and orients in a manner similar to that in the crystal structure of active IRK.

[0416] Steric Influence of the Juxtamembrane Region on the Activation Segment

[0417] While the majority of interactions between the juxtamembrane segment and the catalytic domain are directed towards the N-terminal lobe, strand Ex1 forms a limited set of interactions with the C-terminal lobe that may serve a regulatory role. Superposition of EphB2 with active IRK illustrates how the side chain of the phosphoregulatory residue Tyr/Phe 604 impedes the activation segment from adopting a productive conformation (FIG. 3d). In autoinhibited EphB2, the side chain of Tyr 750 adopts an alternate conformation from that of the corresponding residue Phe 1128 in active IRK. This avoids a steric clash with the side chain of Tyr/Phe604. The alternate conformation of Tyr 750, in turn, impedes the activation segment from adopting a path observed in active IRK due to a steric clash with Ser 776 (Thr 1154 in IRK). Interestingly, the side chain conformation of Tyr 750 in EphB2, Tyr 382 in Src and Hck, and Phe 1128 in IRK all correlate with their activation segments adopting non-productive conformations. This may be indicative of a more general function in protein kinases for position 750 in regulating the conformation of the activation segment.

[0418] The Phosphoregulatory Switch

[0419] The ability to oscillate between catalytically active and repressed states in a regulated manner is the key to the function of protein kinases as versatile molecular switches. In EphB2, EphA4, and most likely Eph RTKs in general, the switch to an active state is coordinated by phosphorylation at highly conserved sites within both the juxtamembrane region and the catalytic domain. The mechanism by which phosphorylation at sites within the activation segment stimulate protein kinases is relatively well understood (reviewed by Johnson et al., 1996) and by inference, phosphorylation of EphB2 at Tyr 788 likely promotes the ordering of the activation segment to a catalytically competent conformation.

[0420] In contrast, phosphorylation at Tyr/Phe 604 and 610 may serve to destabilize the juxtamembrane structure and cause it to dissociate from the catalytic domain. This would allow for a return of the N-terminal lobe to an undistorted active conformation.

[0421] The EphB2 crystal structure helps to explain how phosphorylation at each of the two phosphoregulatory sites could destabilize the juxtamembrane structure and cause its release from the catalytic domain. The environment around each of the two switch regions is hydrophobic, but solvent exposed, and thus could accommodate either tyrosine or phenylalanine at positions 604 and 610 with little or no reorganization of the juxtamembrane structure. However, substitution with phosphotyrosine appears less tolerable due to steric and electrostatic clashes involving the bulky anionic phosphate group. In ‘switch region 1’, the phosphorylation of Tyr/Phe 604 would place a phosphate group within van der Waals contact of Asp 606, Pro 607 and Ile 681. Furthermore, the side chain of Asp 606 dominates the electrostatic environment around Tyr/Phe 604 such that the introduction of a phosphate group would generate repulsive electrostatic forces (FIG. 4). The electrostatic environment around ‘switch region 2’ is also dominated by negatively charged amino acids, namely Asp 606, Glu 611, Asp 612, Glu 615, and Glu 619. Thus, phosphorylation of Tyr 610 would also generate repulsive electrostatic forces, which are likely essential for the expulsion of this residue from its binding pocket since a phosphate group could be accommodated sterically.

[0422] Three other highly conserved tyrosine residues have been identified as in vivo phosphorylation sites in EphB2 and EphB5, namely tyrosines 667, 744 and 750 (FIG. 3c). Although their roles in regulating Eph receptor kinase activity have not been probed by mutagenesis, all three sites appear well positioned to influence the stability of the autoinhibited structure and hence Eph receptor activity (FIG. 3). For example, phosphorylation of Tyr 667 could promote a catalytically competent state by destabilizing the tight association of helix αC with β-strands 3, 4 and 5 observed in the autoinhibited state. In addition, phosphorylation of Tyr 744 and Tyr 750, which line the cleft region through which the juxtamembrane strand Ex1 navigates, could amplify the effect of phosphorylation at Tyr 604.

[0423] Function of the EphA4 Juxtamembrane Segment Probed by Mutagenesis

[0424] Previously, a cytoplasmic fragment of the EphA4 receptor tyrosine kinase, consisting of the juxtamembrane segment, the catalytic domain and the SAM domain, has been shown to require autophosphorylation for maximal activation (Binns et al., 2000). The importance of autophosphorylation was revealed by a lag period at the start of in vitro kinase reactions employing the dephosphorylated form of the EphA4 enzyme. This lag period was greatly reduced by pre-incubation of the EphA4 fragment with ATP or by deletion of the entire juxtamembrane segment. In contrast, mutation to phenylalanine of either Tyr 604 or Tyr 610 reduced the specific activity of the enzyme, while mutation of both sites in tandem drastically impaired catalytic function (<10% relative to WT). These results are consistent with the mechanism of autoinhibition suggested by the EphB2 crystal structure.

[0425] In order to test the crystallographic findings and to probe the regulation of Eph receptor catalytic activity in more detail, additional site-directed mutations were generated in the full-length murine EphB2 receptor expressed in COS-1 cells and in a murine EphA4 receptor fragment expressed in bacteria, corresponding in content to the EphB2 construct used for the structure determination. For the sake of discussion, the murine EphB2 numbering scheme has been employed for all mutants and the corresponding EphA4 residue numbers are listed in parentheses. Each mutation was generated in the catalytically repressed Tyr 604/610 Phe double mutant background and was tested for its ability to restore catalytic function. The mutations include a small N-terminal deletion of residues 595 to 606 (ΔJX1) encompassing strand Ex1 and the first phosphoregulatory site, an intermediate N-terminal deletion of residues 599 to 610 (ΔJX1+2) that encompasses strand Ex1, the first phosphoregulatory site, helix αA′ and the second phosphoregulatory site, and a full juxtamembrane segment deletion of residues 599 to 621 (ΔJX_(all)). In addition, six separate point mutations were generated in both the juxtamembrane region and the kinase domain (Pro607Gly, Phe608Asp, Phe620Asp, Tyr604/610Glu, Ser680Trp, Gln684Trp) that were predicted to destabilize the interaction of the kinase domain with the juxtamembrane segment. Lastly, the ΔJX1+2 mutation was combined with the Phe620Asp mutation (ΔJX1+2 plus Phe620Asp) and the Ser680Trp mutation was combined with the Gln684Trp mutation (Ser680Trp/Gln684Trp). The Tyr604/610Phe double mutant and the wild type proteins were analyzed concomitantly as reference points for the fully repressed (0%) and active (100%) states, respectively. The activities of the EphA4 proteins expressed in bacteria were tested for their ability to induce protein tyrosine phosphorylation in vivo (FIG. 5a), and to autophosphorylate and to phosphorylate enolase in vitro (FIG. 5b). EphA4 proteins were also tested for their ability to phosphorylate a peptide substrate using a continuous spectophotometric assay (FIG. 5c). Lastly, full-length EphB2 proteins expressed in COS-1 cells were tested for their ability to autophosphorylate in vivo and to autophosphorylate and phosphorylate enolase in vitro (FIG. 5d).

[0426] The two partial N-terminal juxtamembrane deletions when introduced into the EphA4 construct significantly increased kinase activity in all four assays, restoring catalytic function as measured by the spectrophotometric assay to 136% and 216% of wild-type activity in the case of ΔJX1 and the ΔJX1+2 deletions, respectively. A similar effect was observed for the ΔJX1+2 deletion introduced into full-length EphB2.

[0427] Mutation of Phe 608 in EphA4, which locates to helix αA′, gave very weak restoration of catalytic function. This result is consistent with the variability of position 608 amongst the Eph receptor family members (42% identity). In contrast, mutation in both EphA4 and EphB2 constructs of the highly conserved Pro 607 (95% identity), which initiates helix αA′, to Gly greatly enhanced catalytic function in all four assays, quantitated at 122% of wild-type activity by the spectrophotometric assay. This result is consistent with a role for Pro607, suggested by the crystal structure, in stabilizing helix αA′ by imposing conformational rigidity, or in promoting the association of juxtamembrane and N-terminal kinase lobe elements through hydrophobic interactions. Similarly, mutation of the highly conserved Phe 620 (95% identity) at the terminus of helix aB′ to Asp also restored catalytic function in the four assays tested. Phe 620 is notable because it contributes to the hydrophobic pocket into which the phosphoregulatory residue Tyr/Phe 610 binds; its substitution with Asp is predicted to disrupt the hydrophobic interaction with Tyr/Phe 610, and to clash electrostatically with the surrounding negatively charged groups in a manner mimicking phosphorylation of Tyr/Phe 610.

[0428] The introduction of point mutations into the kinase domain at the interface with the juxtamembrane region also restored catalytic function. Mutation of Ser680 (82% identity) to Trp in both EphA4 and EphB2 constructs gave modest restoration with the phosphorylation of peptide substrate being restored to 41% of wild-type activity. Mutation of the absolutely conserved Gln684 (100% identity) to Trp in EphB2 resulted in a greater increase in kinase activity, as did the double mutation Ser 680Trp/Gln684Trp. Both mutations map to helix αC and are predicted to sterically perturb the association of the juxtamembrane region with the N-terminal catalytic lobe.

[0429] Robust restoration of activity was also observed for the EphA4 and EphB2 mutants ΔJX_(all), Tyr604/610Glu, and ΔJX1+2 plus Phe620Asp, although the relative restoration as measured by the various assays differed to a small degree. The restoration of activity by the ΔJX1 mutant confirms that the juxtamembrane segment is not absolutely required for kinase function, the restoration by the Tyr604/610 Glu mutation suggests that the addition of negative charges at positions 604 and 610 is an important component of juxatmembrane destabilization and the relief of autoinhibition. Lastly, the finding that none of the EphB2 mutants are as active as the wild-type enzyme may indicate that these mutants have perturbed some aspect of the oligomerization event that is needed for maximal activation of the full-length receptor.

[0430] Overall, the mutagenesis results support a model for the regulation of receptor catalytic function by the juxtamembrane segment, shown in FIG. 6. Strand Ex1 and helix αA′ of the juxtamembrane segment contribute to the inhibitory effect on the catalytic domain, and the release of these elements from their association with the catalytic domain is a requirement for catalytic activation. Physiologically, this would be accomplished by phosphorylation at the Tyr 604 and 610 regulatory sites and potentially at additional sites. The strong conservation of residues involved in the inhibitory interaction suggests that this regulatory mechanism is conserved for all Eph receptor family members.

[0431] Comparison of Autoinhibitory Mechanisms of EphB2 and TGFβR1 Receptor Kinase

[0432] Analysis of the TGFβR1 serine/threonine kinase has revealed a role for the juxtamembrane Gly/Ser/Thr-rich motif (“GS segment”) in regulating catalytic activity. As with Eph receptor tyrosine kinases, TGFβR1 kinases require phosphorylation at sites within the juxtamembrane segment for subsequent phosphorylation of target Smad proteins (Macias-Silva et al, 1996). The regulatory mechanism revealed by the X-ray crystal structure of a cytoplasmic fragment of TGFβR1 in complex with FKBP12 (Huse et al, 1999) shows some parallels to EphB2. In both structures, the intramolecular engagement of the juxtamembrane segment induces conformational distortions in the catalytic domain that impinge on kinase function. In addition, the induced distortions impact on the relative positioning and/or conformation of helix αC. Beyond these similarities, however, the inhibitory mechanisms, including the mode of juxtamembrane association with the catalytic domain and the resulting basis for inhibition, diverge. Perhaps the most significant difference relates to the potential involvement of FKBP12 in stabilizing the inhibited structure of TGFβR1, whereas EphB2 achieves an autoinhibited state independently. Nonetheless, the data for EphB2 indicate that receptor tyrosine kinases and receptor serine/threonine kinases have in some cases converged on a related regulatory mechanism in which the juxtamembrane region inhibits the kinase domain in the inactive state, and is potentially liberated to interact with downstream targets upon autophosphorylation.

[0433] Discussion

[0434] Why does EphB2 employ a rather complex mechanism of autoregulation, involving the non-catalytic juxtamembrane region? One possible benefit may be to block any potential signaling activity intrinsic to the juxtamembrane sequence. In particular, phosphorylation of tyrosines 604 and 610 in EphB2 creates docking sites for SH2 domain proteins. Sequestering these tyrosines decreases their chance of becoming adventitiously phosphorylated and thereby inappropriately transmitting a signal through the recruitment of downstream targets. The coordination of kinase activation with the release of binding sites for targets is reminiscent of Src family cytoplasmic tyrosine kinase, in which the SH2 and SH3 domains engage internal ligands in a fashion that both inhibits the activity of the kinase domain and hinders interactions of the SH2 and SH3 domains with other binding partners (Sicheri et al., 1997; Xu et al., 1997).

[0435] The involvement of the juxtamembrane sequence in autoregulation of EphB2 activity may also set a phosphorylation threshold that must be exceeded to induce receptor activation. Full stimulation of Eph receptors apparently requires autophosphorylation at multiple sites within both the activation segment and juxtamembrane region. The use of at least two distinct phosphoregulatory steps may preclude inappropriate Eph receptor activation resulting from basal levels of kinase activity. Since Eph receptors have powerful biological activities during embryogenesis and postnatally, their aberrant activation would be expected to have severe phenotypic consequences, which could be avoided by requiring multi-site phosphorylation of the receptor.

[0436] Are the Eph receptors unique among RTKs in employing cytoplasmic elements outside the catalytic domain to regulate kinase activity? A variety of data obtained for the platelet-derived growth factor β receptor (PDGFR), the closely related colony stimulating factor-1 receptor (c-Fms), stem cell factor receptor (Kit), and the Flt3 receptor raise the possibility that this may in fact be a more widespread phenomenon. Biochemical analysis and mutagenesis of the PDGFR-β has suggested that autophosphorylation of juxtamembrane tyrosines 579 and 581 is required for stimulation of receptor kinase activity by PDGF, potentially by allowing subsequent phosphorylation of tyrosine 857 in the activation segment (Baxter et al., 1998). Conversion of these juxtamembrane tyrosines to phenylalanine inhibits receptor activation, while their phosphorylation creates a binding site for the Src SH2 domain, resulting in Src recruitment to the receptor. Thus, autophosphorylation within the juxtamembrane region of the PDGFR-β may couple receptor activation to the exposure of SH2 domain-binding sites, as appears to be the case for Eph receptors. Consistent with the notion that the juxtamembrane region of the PDGFR-β exerts an inhibitory influence on kinase activity, substitution of a valine residue, just N-terminal to the regulatory tyrosines, results in constitutive receptor activation in vitro and in vivo (Irusta and DiMaio, 1998). In addition to the PDGFR-β, the juxtamembrane regions of c-Fms (Myles et al., 1994), Kit, and Flt3 receptors have been implicated in regulation of tyrosine kinase activity. Oncogenic variants of Kit identified in human and murine mast cell leukemias carry either amino acid substitutions or deletions in the juxtamembrane region, which result in constitutive activation of the kinase domain (Tsujimura et al., 1996)(see FIG. 1). Remarkably a majority of human gastrointestinal stromal tumors (GIST) have activating Kit mutations that introduce substitutions or deletions into a short segment of the juxtamembrane region, and are strongly implicated in the etiology of these tumors (Hirota et al, 1998; Nakahara et al; 1998; Anderson, 1998). Furthermore, approximately 20% of acute myeloid leukemias have internal tandem duplications of Flt3 that create in-frame insertions of variable length in the juxtamembrane region, leading to ligand-independent kinase activity and oncogenic acitvation (Nakao et al, 1996; Yokota et al, 1997; Hayakawa et al, 2000). Thus, Kit and Flt3 juxtamembrane regions may repress kinase activity, and juxtamembrane mutations that relieve this inhibition can result in human cancers.

[0437] A similar situation may pertain for the insulin receptor, which upon activation becomes autophosphorylated within the juxtamembrane region and consequently binds targets such as IRS-1 and ShcA, which possess PTB domains. Kinetic analysis of wild type and mutant insulin receptors has suggested that the insulin receptor juxtamembrane region acts as an intrasteric inhibitor to block the kinase domain active site, in a fashion that is relieved by autophosphorylation of juxtamembrane tyrosines (Cann et al., 2000).

[0438] Many RTKs have C-terminal tails that upon activation become phosphorylated at SH2/PTB domain-binding sites. Structural analysis of the Tie2/Tek receptor cytoplasmic region has indicated that in the inactive state the tail interacts with the kinase domain in a way that partially occludes the C-terminal tyrosines and the peptide binding site (Shewchuk et al., 2000). This raises the possibility that autophosphorylation of the Tie2 tail causes a conformational change that exposes both C-terminal phosphotyrosine sites as well as the substrate binding site of the kinase domain.

[0439] Thus the juxtamembrane and C-terminal segments of RTKs may play a pivotal role in regulating the kinase domain, and in coordinating enzymatic activation with the exposure of motifs that bind cytoplasmic targets.

[0440] In addition to revealing an unexpected level of complexity in the regulation of RTKs, these observations have interesting implications for the design of RTK inhibitors. The structure of the Ab1 kinase bound to the inhibitor STI-571 suggests that this compound binds selectively to the inactive form of the kinase (Schindler et al., 2000). The unusual structure of autoinhibited EphB2 suggests the possibility of isolating inhibitors that bind specifically to the inactive conformation of the kinase. Indeed, if this mode of intrasteric regulation is a more common feature of RTKs, this might be a general strategy for the identification of selective RTK inhibitors.

[0441] The structure of EphB2 reveals an entirely novel mechanism for RTK autoregulation.

[0442] All publications mentioned in the above specification are herein incorporated by reference. Various modifications and variations of the described methods and system of the invention will be apparent to those skilled in the art without departing from the scope and spirit of the invention. Although the invention has been described in connection with specific preferred embodiments, it should be understood that the invention as claimed should not be unduly limited to such specific embodiments. Indeed, various modifications of the described modes for carrying out the invention which are obvious to those skilled in chemistry, biology or related fields are intended to be within the scope of the following claims. TABLE 1 Data collection, structure determination and refinement statistics SeMet MAD Analysis Native λ₁ = 0.9790 Å λ₂ = 0.9788 Å λ₃ = 0.9770 Å (AMP-PNP) Spacegroup P2₁ P2₁ P2₁ P1 Resolution (Å) 2.3 2.3 2.3 1.9 Reflections total/unique 185034/52252 188170/52750 186452/52855  80035/43865 Completeness (%)* 97.5 (91.2) 97.6 (91.7) 97.6 (90.8) 90.3 (55.9) Rsym (%)*^(†)  7.4 (26.2)  7.5 (27.9)  8.5 (38.7)  3.3 (14.6) <I/σ>* 15.6 (4.0)  16.1 (3.9)  14.9 (3.1)  20.9 (4.1)  Phasing Power^(‡)    0/2.59  2.71/4.11  2.08/3.40 — (ISO/ANO) Refinement (AMP-PNP complex) Resolution Range (Å) 30-1.9 Average B value (Å²) 24.9 Reflections Rmsd for B values (Å²) 1.42 all data 42903 Rmsd for bonds (Å) 0.007 |F|>2σ 39931 Rmsd for angles (°) 1.09 R_(factor)/R_(free)(%)** Number of non-hydrogen protein atoms 4311 all data 24.1/27.7 Number of non-hydrogen nucleotide atoms 20 |F|>2σ 23.2/26.9 Number of water molecules 263

[0443] TABLE 2 Intermolecular contacts of the Juxtamembrane Region and Kinase Domain of an Eph Receptor No. Kinase of Domain/ Atom- Juxtamembrane Distance ic Juxtamembrane Region Between Atomic Inter- Region Atomic Atomic Interaction action Atomic Contact Contact Contacts Property 1 Phe/Tyr 604 CB Met 748 CE 4.58 hydrophobic 2 Phe/Tyr 604 N Met 748 O 2.83 H-bond 3 Phe/Tyr 604 CD2 Tyr 750 CD1 3.78 Hydrophobic 4 Phe/Tyr 604 CE2 Tyr 750 CE1 4.12 Hydrophobic 5 Phe/Tyr 604 CD1 Phe 685 CE2 4.06 Hydrophobic 6 Ile 605 N Gln 684 OE1 2.83 H-bond 7 Ile 605 O Gln 684 NE2 3.00 H-bond 8 Phe/Tyr 604 CE1 Gln 684 CD 4.11 van der Waal 9 Pro 607 CD Ile 681 CG1 3.85 Hydrophobic 10 Pro 607 CB Ser 680 OG 3.16 van der Waal 11 Phe 608 CZ Asp 674 OD1 3.27 van der Waal 12 Phe 608 CZ Ser 677 CB 4.35 van der Waal 13 Phe 608 CE2 Arg 673 CG 3.79 Hydrophobic 14 Pro 613 CB Arg 673 CD 3.60 Hydrophobic 15 Asn 614 OD1 Arg 672 NH1 2.87 H-bond 16 Val 617 CG2 Leu 676 CD1 4.69 Hydrophobic 17 Val 617 CG2 Ser 680 CB 4.15 Hydrophobic 18 Val 617 CG2 Leu 676 CB 4.10 Hydrophobic 19 Ala 621 CB Leu 693 CD2 3.98 Hydrophobic 20 Phe 620 CD1 Gln 684 CG 3.60 Hydrophobic 21 Phe 620 CE1 Gln 684 CD 3.77 Hydrophobic 22 Phe 620 CB Gln 683 O 4.15 van der Waal 23 Phe 620 O Gln 683 O 3.41 H-bond 24 Ala 616 CA Ser 680 CB 3.8 Hydrophobic 25 Tyr/Phe 604 CE2 Asp 606 CB 4.26 Hydrophobic 26 Pro 607 CD Asp 606 OD1 3.28 van der Waal 27 Asp 606 O Thr 609 OG1 2.72 Hydrogen bond 28 Asp 606 O Thr 609 N 2.90 Hydrogen bond 29 Asp 606 CB Thr 609 CG2 3.56 Hydrophobic 30 Phe 604 CZ Pro 607 CD 3.90 Hydrophobic 31 Pro 607 O Phe 610 N 3.08 Hydrogen bond 32 Phe 608 CD2 Pro 613 CG 4.43 Hydrophobic 33 Phe 610 CE1 Ile 605 CG2 3.48 Hydrophobic 34 Phe 610 CZ Phe 620 CE1 3.91 Hydrophobic 35 Phe 610 CE1 Ala 616 CB 3.91 Hydrophobic 36 Phe 610 CD2 Glu 615 CG 3.74 Hydrophobic 37 Asp 612 O Glu 615 N 2.73 Hydrogen bond 38 Phe 608 N Asp 606 OD1 2.83 Hydrogen Bond 39 Asp 612 OD1 Asn 614 ND2 3.09 Hydrogen bond 40 Asp 612 OD1 Asn 614 N 3.11 Hydrogen bond 41 Asn 614 O Arg 618 N 3.16 Hydrogen bond 42 Pro 613 O Val 617 N 3.59 Weak hydrogen bond, van der Waal 43 Glu 615 O Glu 619 N 3.06 Hydrogen Bond 44 Glu 615 OE1 Glu 619 OE1 2.64 Hydrogen Bond 45 Phe 620 N Ala 616 O 2.96 Hydorgen Bond 46 Glu 619 OE2 Phe 620 CZ 4.03 Van der waals 47 Ala 621 N Val 617 O 2.91 Hydrogen Bond 48 Ala 621 O Val 617 O 3.25 Hydrogen Bond 49 Ala 621 CB Val 617 CG1 4.16 Hydrophobic

[0444] TABLE 3 REMARK coordinates from minimization and B-factor refinement □ REMARK refinement resolution: 30 - 1.9 A REMARK starting r= 0.2330 free_r= 0.2672 REMARK final  r= 0.2316 free_r= 0.2691 REMARK rmsd bonds= 0.007125  rmsd angles= 1.07641 REMARK B rmsd for bonded mainchain atoms= 1.398 target= 1.5 REMARK B rmsd for bonded sidechain atoms= 1.963 target= 2 REMARK B rmsd for angle mainchain atoms= 2.128 target= 2 REMARK B rmsd for angle sidechain atoms= 2.727 target= 2.5 REMARK target= mlf final wa= 1.79025 REMARK final rweight= 0.1000 (with wa= 1.79025) REMARK md-method= torsion annealing schedule= slowcool REMARK starting temperature= 3000 total md steps= 30 * 6 REMARK cycles= 2 coordinate steps= 20 B-factor steps= 10 REMARK sg= P1 a= 47.052 b= 57.616 c= 67.742 alpha= 112.949 beta= 103.173 gamma= 91.577 REMARK topology file 1 : CNS_TOPPAR:protein.top REMARK topology file 2 : CNS_TOPPAR:dna-rna.top REMARK topology file 3 : CNS_TOPPAR:water.top REMARK topology file 4 : CNS_TOPPAR:ion.top REMARK topology file 5 : adenine.top REMARK parameter file 1 : CNS_TOPPAR:proteinrep.param REMARK parameter file 2 : CNS_TOPPAR:dna-rna_rep.param REMARK parameter file 3 : CNS_TOPPAR:water_rep.param REMARK parameter file 4 : CNS_TOPPAR:ion.param REMARK parameter file 5 : adenine.par REMARK molecular structure file: gen_ab.mtf REMARK input coordinates: ref7b.pdb REMARK reflection file= ../cycle1/amp.cv REMARK ncs= none REMARK B-correction resolution: 6.0 - 1.9 REMARK B-factor correction applied to coordinate arrayB: 0.210 REMARK bulk solvent: density level= 0.37437 e/A{circumflex over ( )}3, B-factor= 62.0599 A{circumflex over ( )}2 REMARK reflections with |Fobs| /sigma_F < 2 rejected REMARK reflections with |Fobs| > 10000 * rms(Fobs) rejected REMARK theoretical total number of refl. in resol. range: 49847 (100.0%) REMARK number of unobserved reflections (no entry or |F|=0):  6944 ( 13.9%) REMARK number of reflections rejected:  2972 ( 6.0%) REMARK total number of reflections used: 39931 ( 80.1%) REMARK number of reflections in working set: 35881 ( 72.0%) REMARK number of reflections in test set:  4050 ( 8.1%) CRYST1 47.052 57.616 67.742 112.95 103.17 91.58 P 1 REMARK FILENAME=′ref7c.pdb′ REMARK DATE:18-Jan-01 11:50:14   created by user: groot REMARK VERSION:1.0 ATOM 1 CB LYS A 602 −9.305 −0.312 −16.924 1.00 36.55 A ATOM 2 CG LYS A 602 −9.592 −1.380 −17.964 1.00 40.76 A ATOM 3 CD LYS A 602 −9.801 −2.735 −17.332 1.00 43.15 A ATOM 4 CE LYS A 602 −10.202 −3.766 −18.379 1.00 46.04 A ATOM 5 NZ LYS A 602 −10.292 −5.135 −17.793 1.00 47.27 A ATOM 6 C LYS A 602 −9.501 2.125 −16.413 1.00 30.61 A ATOM 7 O LYS A 602 −8.689 3.021 −16.178 1.00 31.27 A ATOM 8 N LYS A 602 −7.962 1.290 −18.245 1.00 34.40 A ATOM 9 CA LYS A 602 −9.247 1.097 −17.512 1.00 33.41 A ATOM 10 N ILE A 603 −10.653 1.995 −15.761 1.00 26.03 A ATOM 11 CA ILE A 603 −11.041 2.890 −14.680 1.00 21.35 A ATOM 12 CB ILE A 603 −12.110 3.916 −15.127 1.00 23.23 A ATOM 13 CG2 ILE A 603 −13.424 3.183 −15.474 1.00 23.72 A ATOM 14 CG1 ILE A 603 −12.383 4.899 −13.988 1.00 22.54 A ATOM 15 CD1 ILE A 603 −13.398 5.974 −14.316 1.00 27.41 A ATOM 16 C ILE A 603 −11.648 2.050 −13.553 1.00 17.90 A ATOM 17 O ILE A 603 −12.280 1.022 −13.815 1.00 16.74 A ATOM 18 N PHE A 604 −11.460 2.501 −12.313 1.00 12.95 A ATOM 19 CA PHE A 604 −11.981 1.815 −11.122 1.00 14.58 A ATOM 20 CB PHE A 604 −11.309 2.347 −9.848 1.00 13.58 A ATOM 21 CG PHE A 604 −11.978 1.890 −8.569 1.00 10.12 A ATOM 22 CD1 PHE A 604 −11.890 0.565 −8.165 1.00 12.14 A ATOM 23 CD2 PHE A 604 −12.683 2.785 −7.770 1.00 12.13 A ATOM 24 CE1 PHE A 604 −12.493 0.132 −6.972 1.00 12.82 A ATOM 25 CE2 PHE A 604 −13.293 2.368 −6.574 1.00 13.41 A ATOM 26 CZ PEE A 604 −13.194 1.036 −6.176 1.00 11.79 A ATOM 27 C PHE A 604 −13.488 2.027 −10.968 1.00 14.34 A ATOM 28 O PEE A 604 −13.972 3.155 −11.068 1.00 14.17 A ATOM 29 N ILE A 605 −14.205 0.946 −10.671 1.00 14.05 A ATOM 30 CA ILE A 605 −15.658 0.985 −10.471 1.00 15.51 A ATOM 31 CB ILE A 605 −16.376 −0.024 −11.404 1.00 14.91 A ATOM 32 CG2 ILE A 605 −17.892 0.062 −11.203 1.00 17.40 A ATOM 33 CG1 ILE A 605 −16.034 0.269 −12.868 1.00 16.70 A ATOM 34 CD1 ILE A 605 −16.412 1.664 −13.326 1.00 20.67 A ATOM 35 C ILE A 605 −15.976 0.616 −9.010 1.00 15.81 A ATOM 36 O ILE A 605 −15.679 −0.491 −8.569 1.00 17.18 A ATOM 37 N ASP A 606 −16.547 1.548 −8.253 1.00 16.32 A ATOM 38 CA ASP A 606 −16.902 1.291 −6.855 1.00 17.50 A ATOM 39 CB ASP A 606 −17.542 2.550 −6.253 1.00 18.47 A ATOM 40 CG ASP A 606 −17.884 2.403 −4.775 1.00 19.43 A ATOM 41 OD1 ASP A 606 −17.942 1.262 −4.272 1.00 20.86 A ATOM 42 OD2 ASP A 606 −18.114 3.440 −4.115 1.00 20.82 A ATOM 43 C ASP A 606 −17.899 0.128 −6.844 1.00 18.22 A ATOM 44 O ASP A 606 −19.001 0.249 −7.371 1.00 17.14 A ATOM 45 N PRO A 607 −17.517 −1.014 −6.247 1.00 17.74 A ATOM 46 CD PRO A 607 −16.268 −1.278 −5.509 1.00 17.77 A ATOM 47 CA PRO A 607 −18.427 −2.164 −6.209 1.00 18.01 A ATOM 48 CB PRO A 607 −17.621 −3.247 −5.470 1.00 17.22 A ATOM 49 CG PRO A 607 −16.645 −2.465 −4.633 1.00 18.76 A ATOM 50 C PRO A 607 −19.753 −1.836 −5.536 1.00 16.89 A ATOM 51 O PRO A 607 −20.780 −2.404 −5.878 1.00 17.69 A ATOM 52 N PEE A 608 −19.744 −0.897 −4.602 1.00 17.34 A ATOM 53 CA PEE A 608 −20.989 −0.557 −3.946 1.00 19.12 A ATOM 54 CB PHE A 608 −20.738 0.133 −2.613 1.00 18.91 A ATOM 55 CG PEE A 608 −20.319 −0.799 −1.511 1.00 18.72 A ATOM 56 CD1 PHE A 608 −20.047 −0.291 −0.251 1.00 18.84 A ATOM 57 CD2 PEE A 608 −20.171 −2.166 −1.729 1.00 18.90 A ATOM 58 CE1 PHE A 608 −19.632 −1.114 0.776 1.00 20.59 A ATOM 59 CE2 PHE A 608 −19.750 −3.011 −0.693 1.00 22.14 A ATOM 60 CZ PHE A 608 −19.482 −2.478 0.559 1.00 19.82 A ATOM 61 C PEE A 608 −21.928 0.292 −4.795 1.00 18.67 A ATOM 62 O PHE A 608 −22.993 0.678 −4.319 1.00 18.02 A ATOM 63 N TER A 609 −21.546 0.609 −6.031 1.00 18.97 A ATOM 64 CA THR A 609 −22.463 1.373 −6.868 1.00 19.12 A ATOM 65 CB THR A 609 −21.748 2.284 −7.911 1.00 17.33 A ATOM 66 OG1 THR A 609 −20.955 1.487 −8.799 1.00 17.70 A ATOM 67 CG2 THR A 609 −20.886 3.309 −7.216 1.00 18.57 A ATOM 68 C THR A 609 −23.313 0.342 −7.606 1.00 19.52 A ATOM 69 O THR A 609 −24.302 0.683 −8.247 1.00 19.06 A ATOM 70 N PHE A 610 −22.925 −0.928 −7.524 1.00 18.09 A ATOM 71 CA PHE A 610 −23.709 −1.967 −8.181 1.00 19.10 A ATOM 72 CB PHE A 610 −22.955 −3.299 −8.223 1.00 20.69 A ATOM 73 CG PHE A 610 −21.861 −3.357 −9.240 1.00 21.23 A ATOM 74 CD1 PHE A 610 −20.707 −2.610 −9.082 1.00 22.59 A ATOM 75 CD2 PHE A 610 −21.973 −4.184 −10.350 1.00 23.50 A ATOM 76 CE1 PHE A 610 −19.678 −2.681 −10.007 1.00 21.63 A ATOM 77 CE2 PHE A 610 −20.942 −4.261 −11.285 1.00 23.79 A ATOM 78 CZ PHE A 610 −19.791 −3.504 −11.107 1.00 20.78 A ATOM 79 C PHE A 610 −25.000 −2.167 −7.386 1.00 20.52 A ATOM 80 O PHE A 610 −24.986 −2.148 −6.150 1.00 20.43 A ATOM 81 N GLU A 611 −26.111 −2.343 −8.095 1.00 20.58 A ATOM 82 CA GLU A 611 −27.404 −2.571 −7.459 1.00 21.53 A ATOM 83 CB GLU A 611 −28.485 −2.853 −8.523 1.00 22.75 A ATOM 84 CG GLU A 611 −28.714 −1.718 −9.518 0.00 23.28 A ATOM 85 CD GLU A 611 −29.783 −2.041 −10.554 0.00 23.79 A ATOM 86 OE1 GLU A 611 −30.061 −1.175 −11.409 0.00 24.06 A ATOM 87 OE2 GLU A 611 −30.345 −3.158 −10.516 0.00 24.06 A ATOM 88 C GLU A 611 −27.257 −3.790 −6.546 1.00 21.14 A ATOM 89 O GLU A 611 −27.861 −3.857 −5.479 1.00 20.93 A ATOM 90 N ASP A 612 −26.445 −4.746 −6.992 1.00 21.15 A ATOM 91 CA ASP A 612 −26.160 −5.966 −6.239 1.00 21.15 A ATOM 92 CB ASP A 612 −26.738 −7.203 −6.946 1.00 22.41 A ATOM 93 CG ASP A 612 −26.407 −8.504 −6.220 1.00 26.34 A ATOM 94 OD1 ASP A 612 −25.869 −8.451 −5.091 1.00 26.08 A ATOM 95 OD2 ASP A 612 −26.693 −9.588 −6.776 1.00 28.73 A ATOM 96 C ASP A 612 −24.641 −6.106 −6.114 1.00 20.74 A ATOM 97 O ASP A 612 −23.967 −6.530 −7.051 1.00 18.43 A ATOM 98 N PRO A 613 −24.085 −5.745 −4.948 1.00 22.26 A ATOM 99 CD PRO A 613 −24.796 −5.172 −3.790 1.00 21.09 A ATOM 100 CA PRO A 613 −22.642 −5.825 −4.692 1.00 23.09 A ATOM 101 CB PRO A 613 −22.551 −5.579 −3.188 1.00 23.78 A ATOM 102 CG PRO A 613 −23.662 −4.598 −2.957 1.00 24.95 A ATOM 103 C PRO A 613 −22.001 −7.149 −5.112 1.00 24.21 A ATOM 104 O PRO A 613 −20.830 −7.182 −5.486 1.00 24.14 A ATOM 105 N ASN A 614 −22.764 −8.238 −5.060 1.00 24.32 A ATOM 106 CA ASN A 614 −22.232 −9.544 −5.445 1.00 24.86 A ATOM 107 CB ASN A 614 −23.242 −10.652 −5.162 1.00 28.16 A ATOM 108 CG ASN A 614 −23.520 −10.813 −3.699 1.00 30.99 A ATOM 109 OD1 ASN A 614 −22.600 −10.994 −2.903 1.00 33.48 A ATOM 110 ND2 ASN A 614 −24.795 −10.750 −3.325 1.00 34.69 A ATOM 111 C ASN A 614 −21.866 −9.598 −6.912 1.00 25.02 A ATOM 112 O ASN A 614 −21.035 −10.412 −7.329 1.00 23.77 A ATOM 113 N GLU A 615 −22.498 −8.742 −7.706 1.00 22.98 A ATOM 114 CA GLU A 615 −22.213 −8.728 −9.129 1.00 23.04 A ATOM 115 CB GLU A 615 −23.144 −7.762 −9.863 1.00 24.89 A ATOM 116 CG GLU A 615 −22.838 −7.681 −11.345 1.00 29.63 A ATOM 117 CD GLU A 615 −22.902 −9.036 −12.032 1.00 33.50 A ATOM 118 OE1 GLU A 615 −22.270 −9.188 −13.103 1.00 35.83 A ATOM 119 OE2 GLU A 615 −23.589 −9.949 −11.511 1.00 35.71 A ATOM 120 C GLU A 615 −20.766 −8.312 −9.348 1.00 19.65 A ATOM 121 O GLU A 615 −20.079 −8.854 −10.211 1.00 19.95 A ATOM 122 N ALA A 616 −20.306 −7.340 −8.569 1.00 19.06 A ATOM 123 CA ALA A 616 −18.932 −6.884 −8.702 1.00 16.63 A ATOM 124 CB ALA A 616 −18.676 −5.728 −7.763 1.00 16.24 A ATOM 125 C ALA A 616 −17.982 −8.037 −8.401 1.00 15.74 A ATOM 126 O ALA A 616 −16.929 −8.180 −9.031 1.00 15.81 A ATOM 127 N VAL A 617 −18.353 −8.880 −7.447 1.00 15.22 A ATOM 128 CA VAL A 617 −17.493 −10.001 −7.106 1.00 14.30 A ATOM 129 CB VAL A 617 −18.003 −10.750 −5.865 1.00 14.79 A ATOM 130 CG1 VAL A 617 −17.028 −11.869 −5.501 1.00 16.38 A ATOM 131 CG2 VAL A 617 −18.123 −9.781 −4.703 1.00 11.27 A ATOM 132 C VAL A 617 −17.337 −10.979 −8.256 1.00 14.61 A ATOM 133 O VAL A 617 −16.215 −11.372 −8.608 1.00 14.99 A ATOM 134 N ARG A 618 −18.445 −11.370 −8.868 1.00 16.24 A ATOM 135 CA ARG A 618 −18.353 −12.322 −9.964 1.00 18.27 A ATOM 136 CB ARG A 618 −19.752 −12.808 −10.375 1.00 20.76 A ATOM 137 CG ARG A 618 −20.691 −11.740 −10.838 0.00 21.07 A ATOM 138 CD ARG A 618 −22.044 −12.351 −11.112 0.00 22.19 A ATOM 139 NE ARG A 618 −22.650 −12.891 −9.899 0.00 22.97 A ATOM 140 CZ ARG A 618 −23.853 −13.451 −9.857 0.00 23.42 A ATOM 141 NH1 ARG A 618 −24.575 −13.545 −10.965 0.00 23.69 A ATOM 142 NH2 ARG A 618 −24.342 −13.903 −8.711 0.00 23.69 A ATOM 143 C ARG A 618 −17.626 −11.746 −11.168 1.00 18.93 A ATOM 144 O ARG A 618 −16.988 −12.479 −11.928 1.00 21.33 A ATOM 145 N GLU A 619 −17.707 −10.430 −11.334 1.00 18.93 A ATOM 146 CA GLU A 619 −17.059 −9.777 −12.463 1.00 20.86 A ATOM 147 CB GLU A 619 −17.728 −8.439 −12.745 1.00 23.33 A ATOM 148 CG GLU A 619 −19.148 −8.576 −13.213 1.00 30.69 A ATOM 149 CD GLU A 619 −19.640 −7.325 −13.876 1.00 34.05 A ATOM 150 OE1 GLU A 619 −20.842 −7.271 −14.214 1.00 37.39 A ATOM 151 OE2 GLU A 619 −18.821 −6.396 −14.065 1.00 36.23 A ATOM 152 C GLU A 619 −15.564 −9.548 −12.338 1.00 20.77 A ATOM 153 O GLU A 619 −14.829 −9.748 −13.300 1.00 21.23 A ATOM 154 N PHE A 620 −15.113 −9.128 −11.161 1.00 19.38 A ATOM 155 CA PHE A 620 −13.697 −8.841 −10.977 1.00 20.53 A ATOM 156 CB PHE A 620 −13.544 −7.472 −10.326 1.00 19.14 A ATOM 157 CG PHE A 620 −14.366 −6.393 −10.987 1.00 18.99 A ATOM 158 CD1 PHE A 620 −15.303 −5.672 −10.258 1.00 18.77 A ATOM 159 CD2 PHE A 620 −14.193 −6.091 −12.339 1.00 22.01 A ATOM 160 CE1 PHE A 620 −16.061 −4.661 −10.859 1.00 20.15 A ATOM 161 CE2 PHE A 620 −14.947 −5.082 −12.951 1.00 20.05 A ATOM 162 CZ PHE A 620 −15.879 −4.369 −12.205 1.00 18.18 A ATOM 163 C PHE A 620 −12.892 −9.871 −10.190 1.00 22.13 A ATOM 164 O PHE A 620 −11.677 −9.719 −10.037 1.00 21.27 A ATOM 165 N ALA A 621 −13.562 −10.915 −9.704 1.00 22.03 A ATOM 166 CA ALA A 621 −12.906 −11.959 −8.922 1.00 23.00 A ATOM 167 CB ALA A 621 −13.365 −11.873 −7.469 1.00 22.11 A ATOM 168 C ALA A 621 −13.159 −13.368 −9.456 1.00 24.84 A ATOM 169 O ALA A 621 −14.300 −13.748 −9.731 1.00 24.07 A ATOM 170 N LYS A 622 −12.088 −14.146 −9.587 1.00 24.59 A ATOM 171 CA LYS A 622 −12.195 −15.517 −10.074 1.00 26.44 A ATOM 172 CB LYS A 622 −10.842 −16.000 −10.600 1.00 29.90 A ATOM 173 CG LYS A 622 −10.862 −17.445 −11.086 1.00 34.03 A ATOM 174 CD LYS A 622 −9.455 −18.030 −11.189 1.00 36.96 A ATOM 175 CE LYS A 622 −8.623 −17.304 −12.231 1.00 39.89 A ATOM 176 NZ LYS A 622 −7.211 −17.795 −12.281 1.00 41.83 A ATOM 177 C LYS A 622 −12.647 −16.453 −8.956 1.00 26.32 A ATOM 178 O LYS A 622 −12.038 −16.482 −7.885 1.00 25.37 A ATOM 179 N GLU A 623 −13.713 −17.211 −9.202 1.00 25.42 A ATOM 180 CA GLU A 623 −14.222 −18.161 −8.214 1.00 25.52 A ATOM 181 CB GLU A 623 −15.657 −18.582 −8.566 1.00 26.37 A ATOM 182 CG GLU A 623 −16.289 −19.613 −7.627 1.00 26.38 A ATOM 183 CD GLU A 623 −16.521 −19.094 −6.212 1.00 28.72 A ATOM 184 OE1 GLU A 623 −16.905 −17.909 −6.053 1.00 28.21 A ATOM 185 OE2 GLU A 623 −16.328 −19.876 −5.253 1.00 29.13 A ATOM 186 C GLU A 623 −13.302 −19.371 −8.231 1.00 24.77 A ATOM 187 O GLU A 623 −13.131 −20.015 −9.261 1.00 25.82 A ATOM 188 N ILE A 624 −12.686 −19.663 −7.094 1.00 26.18 A ATOM 189 CA ILE A 624 −11.777 −20.798 −6.993 1.00 25.31 A ATOM 190 CB ILE A 624 −10.466 −20.400 −6.263 1.00 25.34 A ATOM 191 CG2 ILE A 624 −9.588 −21.641 −6.048 1.00 23.96 A ATOM 192 CG1 ILE A 624 −9.730 −19.327 −7.070 1.00 24.39 A ATOM 193 CD1 ILE A 624 −8.450 −18.815 −6.426 1.00 25.55 A ATOM 194 C ILE A 624 −12.427 −21.950 −6.236 1.00 25.18 A ATOM 195 O ILE A 624 −13.012 −21.763 −5.170 1.00 25.10 A ATOM 196 N ASP A 625 −12.324 −23.144 −6.801 1.00 26.96 A ATOM 197 CA ASP A 625 −12.890 −24.323 −6.167 1.00 27.95 A ATOM 198 CB ASP A 625 −12.781 −25.528 −7.089 1.00 30.55 A ATOM 199 CG ASP A 625 −13.634 −26.679 −6.625 1.00 34.97 A ATOM 200 OD1 ASP A 625 −14.850 −26.648 −6.907 1.00 37.34 A ATOM 201 OD2 ASP A 625 −13.095 −27.597 −5.963 1.00 34.92 A ATOM 202 C ASP A 625 −12.088 −24.580 −4.902 1.00 27.84 A ATOM 203 O ASP A 625 −10.857 −24.583 −4.937 1.00 26.54 A ATOM 204 N ILE A 626 −12.781 −24.807 −3.791 1.00 27.43 A ATOM 205 CA ILE A 626 −12.111 −25.042 −2.518 1.00 28.27 A ATOM 206 CB ILE A 626 −13.149 −25.293 −1.398 1.00 29.15 A ATOM 207 CG2 ILE A 626 −13.897 −26.591 −1.660 1.00 28.78 A ATOM 208 CG1 ILE A 626 −12.455 −25.330 −0.040 1.00 30.32 A ATOM 209 CD1 ILE A 626 −13.412 −25.148 1.122 1.00 35.27 A ATOM 210 C ILE A 626 −11.099 −26.195 −2.563 1.00 27.88 A ATOM 211 O ILE A 626 −10.116 −26.198 −1.825 1.00 27.54 A ATOM 212 N SER A 627 −11.319 −27.164 −3.442 1.00 29.17 A ATOM 213 CA SER A 627 −10.393 −28.289 −3.538 1.00 29.60 A ATOM 214 CB SER A 627 −10.942 −29.350 −4.483 1.00 29.57 A ATOM 215 OG SER A 627 −10.885 −28.887 −5.818 1.00 31.25 A ATOM 216 C SER A 627 −9.009 −27.858 −4.028 1.00 29.72 A ATOM 217 O SER A 627 −8.072 −28.657 −4.025 1.00 29.55 A ATOM 218 N CYS A 628 −8.888 −26.606 −4.465 1.00 29.03 A ATOM 219 CA CYS A 628 −7.616 −26.075 −4.951 1.00 29.50 A ATOM 220 CB CYS A 628 −7.840 −25.103 −6.128 1.00 28.94 A ATOM 221 SG CYS A 628 −8.593 −25.809 −7.641 1.00 30.55 A ATOM 222 C CYS A 628 −6.871 −25.335 −3.836 1.00 29.48 A ATOM 223 O CYS A 628 −5.665 −25.115 −3.928 1.00 28.60 A ATOM 224 N VAL A 629 −7.592 −24.955 −2.785 1.00 30.83 A ATOM 225 CA VAL A 629 −7.004 −24.218 −1.671 1.00 31.02 A ATOM 226 CB VAL A 629 −7.999 −23.159 −1.128 1.00 32.23 A ATOM 227 CG1 VAL A 629 −7.317 −22.303 −0.052 1.00 32.29 A ATOM 228 CG2 VAL A 629 −8.509 −22.280 −2.264 1.00 31.46 A ATOM 229 C VAL A 629 −6.578 −25.107 −0.498 1.00 32.09 A ATOM 230 O VAL A 629 −7.324 −25.985 −0.063 1.00 32.06 A ATOM 231 N LYS A 630 −5.377 −24.869 0.017 1.00 31.20 A ATOM 232 CA LYS A 630 −4.889 −25.641 1.148 1.00 32.57 A ATOM 233 CB LYS A 630 −3.847 −26.667 0.686 1.00 32.81 A ATOM 234 CG LYS A 630 −4.348 −27.600 −0.410 0.00 33.76 A ATOM 235 CD LYS A 630 −3.253 −28.548 −0.871 0.00 34.37 A ATOM 236 CE LYS A 630 −3.749 −29.493 −1.955 0.00 34.80 A ATOM 237 NZ LYS A 630 −4.215 −28.765 −3.167 0.00 35.13 A ATOM 238 C LYS A 630 −4.286 −24.708 2.190 1.00 31.65 A ATOM 239 O LYS A 630 −3.204 −24.162 2.000 1.00 31.96 A ATOM 240 N ILE A 631 −5.009 −24.513 3.285 1.00 32.38 A ATOM 241 CA ILE A 631 −4.542 −23.655 4.359 1.00 33.62 A ATOM 242 CB ILE A 631 −5.700 −23.282 5.314 1.00 33.44 A ATOM 243 CG2 ILE A 631 −5.155 −22.539 6.532 1.00 33.62 A ATOM 244 CG1 ILE A 631 −6.740 −22.438 4.565 1.00 33.30 A ATOM 245 CD1 ILE A 631 −7.916 −21.992 5.416 1.00 31.54 A ATOM 246 C ILE A 631 −3.464 −24.396 5.142 1.00 34.94 A ATOM 247 O ILE A 631 −3.709 −25.490 5.646 1.00 34.77 A ATOM 248 N GLU A 632 −2.278 −23.797 5.237 1.00 35.73 A ATOM 249 CA GLU A 632 −1.154 −24.396 5.958 1.00 37.69 A ATOM 250 CB GLU A 632 0.167 −24.114 5.236 1.00 38.83 A ATOM 251 CG GLU A 632 0.312 −24.785 3.892 0.00 39.80 A ATOM 252 CD GLU A 632 0.374 −26.290 4.006 0.00 40.38 A ATOM 253 OE1 GLU A 632 1.254 −26.793 4.735 0.00 40.70 A ATOM 254 OE2 GLU A 632 −0.455 −26.970 3.367 0.00 40.70 A ATOM 255 C GLU A 632 −1.047 −23.892 7.394 1.00 38.57 A ATOM 256 O GLU A 632 −1.118 −24.681 8.342 1.00 38.93 A ATOM 257 N GLN A 633 −0.868 −22.583 7.556 1.00 38.28 A ATOM 258 CA GLN A 633 −0.744 −21.995 8.889 1.00 39.08 A ATOM 259 CB GLN A 633 0.739 −21.825 9.250 1.00 40.39 A ATOM 260 CG GLN A 633 1.001 −21.4821 0.712 0.00 41.11 A ATOM 261 CD GLN A 633 2.481 −21.3671 1.028 0.00 41.66 A ATOM 262 OE1 GLN A 633 3.235 −22.3311 0.891 0.00 41.94 A ATOM 263 NE2 GLN A 633 2.904 −20.1831 1.455 0.00 41.94 A ATOM 264 C GLN A 633 −1.455 −20.650 8.994 1.00 39.45 A ATOM 265 O GLN A 633 −1.725 −20.000 7.982 1.00 36.93 A ATOM 266 N VAL A 634 −1.762 −20.238 10.221 1.00 39.17 A ATOM 267 CA VAL A 634 −2.425 −18.960 10.445 1.00 41.26 A ATOM 268 CB VAL A 634 −3.371 −19.013 11.653 1.00 41.53 A ATOM 269 CG1 VAL A 634 −4.109 −17.694 11.778 1.00 42.05 A ATOM 270 CG2 VAL A 634 −4.344 −20.164 11.501 1.00 40.57 A ATOM 271 C VAL A 634 −1.368 −17.900 10.719 1.00 42.58 A ATOM 272 O VAL A 634 −0.569 −18.044 11.649 1.00 43.99 A ATOM 273 N ILE A 635 −1.365 −16.842 9.910 1.00 43.60 A ATOM 274 CA ILE A 635 −0.398 −15.749 10.045 1.00 44.51 A ATOM 275 CB ILE A 635 −0.214 −14.995 8.699 1.00 45.18 A ATOM 276 CG2 ILE A 635 0.860 −13.925 8.841 0.00 45.30 A ATOM 277 CG1 ILE A 635 0.154 −15.979 7.586 0.00 45.40 A ATOM 278 CD1 ILE A 635 1.450 −16.730 7.817 0.00 45.70 A ATOM 279 C ILE A 635 −0.846 −14.744 11.103 1.00 45.18 A ATOM 280 O ILE A 635 −0.281 −14.678 12.197 1.00 45.07 A ATOM 281 N GLY A 636 −1.871 −13.966 10.768 1.00 45.30 A ATOM 282 CA GLY A 636 −2.385 −12.968 11.689 1.00 45.00 A ATOM 283 C GLY A 636 −3.900 −12.992 11.798 1.00 44.80 A ATOM 284 O GLY A 636 −4.550 −13.951 11.375 1.00 44.35 A ATOM 285 N ALA A 637 −4.462 −11.934 12.373 1.00 44.33 A ATOM 286 CA ALA A 637 −5.906 −11.818 12.545 1.00 43.81 A ATOM 287 CB ALA A 637 −6.238 −11.493 13.996 1.00 43.88 A ATOM 288 C ALA A 637 −6.450 −10.729 11.634 1.00 43.58 A ATOM 289 O ALA A 637 −5.828 −9.677 11.465 1.00 42.65 A ATOM 290 N GLY A 638 −7.612 −10.988 11.044 1.00 43.24 A ATOM 291 CA GLY A 638 −8.218 −10.012 10.157 1.00 41.84 A ATOM 292 C GLY A 638 −9.481 −9.419 10.741 1.00 41.01 A ATOM 293 O GLY A 638 −9.978 −9.880 11.773 1.00 41.22 A ATOM 294 N GLU A 639 −10.006 −8.397 10.075 1.00 40.04 A ATOM 295 CA GLU A 639 −11.222 −7.733 10.525 1.00 37.62 A ATOM 296 CB GLU A 639 −11.469 −6.470 9.695 1.00 39.78 A ATOM 297 CG GLU A 639 −12.702 −5.688 10.127 1.00 44.07 A ATOM 298 CD GLU A 639 −13.102 −4.611 9.134 1.00 46.08 A ATOM 299 OE1 GLU A 639 −14.145 −3.961 9.358 1.00 48.25 A ATOM 300 OE2 GLU A 639 −12.381 −4.416 8.128 1.00 47.68 A ATOM 301 C GLU A 639 −12.448 −8.645 10.431 1.00 35.13 A ATOM 302 O GLU A 639 −13.392 −8.509 11.219 1.00 34.00 A ATOM 303 N PHE A 640 −12.430 −9.574 9.477 1.00 31.83 A ATOM 304 CA PHE A 640 −13.560 −10.482 9.278 1.00 30.48 A ATOM 305 CB PHE A 640 −14.083 −10.366 7.832 1.00 29.76 A ATOM 306 CG PHE A 640 −14.482 −8.966 7.433 1.00 28.46 A ATOM 307 CD1 PHE A 640 −13.531 −8.058 6.974 1.00 28.70 A ATOM 308 CD2 PHE A 640 −15.802 −8.545 7.548 1.00 28.68 A ATOM 309 CE1 PHE A 640 −13.889 −6.745 6.636 1.00 27.42 A ATOM 310 CE2 PHE A 640 −16.172 −7.237 7.215 1.00 26.96 A ATOM 311 CZ PHE A 640 −15.211 −6.337 6.759 1.00 27.64 A ATOM 312 C PHE A 640 −13.242 −11.952 9.591 1.00 29.44 A ATOM 313 O PHE A 640 −14.118 −12.817 9.499 1.00 27.82 A ATOM 314 N GLY A 641 −11.998 −12.230 9.966 1.00 28.09 A ATOM 315 CA GLY A 641 −11.611 −13.597 10.266 1.00 28.09 A ATOM 316 C GLY A 641 −10.105 −13.766 10.389 1.00 28.66 A ATOM 317 O GLY A 641 −9.402 −12.833 10.777 1.00 27.98 A ATOM 318 N GLU A 642 −9.609 −14.955 10.052 1.00 27.87 A ATOM 319 CA GLU A 642 −8.185 −15.249 10.140 1.00 28.48 A ATOM 320 CB GLU A 642 −7.969 −16.715 10.559 1.00 31.49 A ATOM 321 CG GLU A 642 −8.655 −17.116 11.879 1.00 35.67 A ATOM 322 CD GLU A 642 −8.289 −18.526 12.345 1.00 38.58 A ATOM 323 OE1 GLU A 642 −8.407 −19.482 11.544 1.00 39.58 A ATOM 324 OE2 GLU A 642 −7.884 −18.676 13.521 1.00 39.80 A ATOM 325 C GLU A 642 −7.419 −14.989 8.844 1.00 27.74 A ATOM 326 O GLU A 642 −7.980 −15.043 7.744 1.00 26.91 A ATOM 327 N VAL A 643 −6.130 −14.693 8.989 1.00 27.11 A ATOM 328 CA VAL A 643 −5.252 −14.461 7.853 1.00 26.42 A ATOM 329 CB VAL A 643 −4.478 −13.134 7.996 1.00 25.95 A ATOM 330 CG1 VAL A 643 −3.732 −12.838 6.728 1.00 25.98 A ATOM 331 CG2 VAL A 643 −5.427 −12.014 8.334 1.00 25.96 A ATOM 332 C VAL A 643 −4.268 −15.620 7.891 1.00 26.37 A ATOM 333 O VAL A 643 −3.519 −15.763 8.858 1.00 24.39 A ATOM 334 N CYS A 644 −4.267 −16.433 6.836 1.00 25.63 A ATOM 335 CA CYS A 644 −3.409 −17.616 6.763 1.00 25.19 A ATOM 336 CB CYS A 644 −4.275 −18.883 6.718 1.00 25.46 A ATOM 337 SG CYS A 644 −5.746 −18.849 7.750 1.00 28.36 A ATOM 338 C CYS A 644 −2.483 −17.655 5.551 1.00 25.37 A ATOM 339 O CYS A 644 −2.556 −16.811 4.657 1.00 25.07 A ATOM 340 N SER A 645 −1.615 −18.658 5.532 1.00 23.66 A ATOM 341 CA SER A 645 −0.709 −18.873 4.419 1.00 24.21 A ATOM 342 CB SER A 645 0.750 −18.801 4.862 1.00 24.10 A ATOM 343 OG SER A 645 1.107 −19.968 5.574 1.00 27.96 A ATOM 344 C SER A 645 −1.025 −20.280 3.949 1.00 23.74 A ATOM 345 O SER A 645 −1.558 −21.088 4.715 1.00 22.82 A ATOM 346 N GLY A 646 −0.703 −20.575 2.695 1.00 24.19 A ATOM 347 CA GLY A 646 −0.985 −21.896 2.171 1.00 22.79 A ATOM 348 C GLY A 646 −0.559 −22.070 0.730 1.00 22.27 A ATOM 349 O GLY A 646 0.255 −21.304 0.208 1.00 21.87 A ATOM 350 N HIS A 647 −1.097 −23.100 0.091 1.00 22.58 A ATOM 351 CA HIS A 647 −0.776 −23.367 −1.296 1.00 24.03 A ATOM 352 CB HIS A 647 −0.024 −24.698 −1.445 1.00 25.12 A ATOM 353 CG HIS A 647 1.316 −24.725 −0.770 1.00 27.93 A ATOM 354 CD2 HIS A 647 2.572 −24.751 −1.278 1.00 28.54 A ATOM 355 ND1 HIS A 647 1.460 −24.753 0.602 1.00 29.81 A ATOM 356 CE1 HIS A 647 2.745 −24.800 0.909 1.00 28.73 A ATOM 357 NE2 HIS A 647 3.441 −24.799 −0.214 1.00 30.01 A ATOM 358 C HIS A 647 −2.054 −23.392 −2.125 1.00 22.29 A ATOM 359 O HIS A 647 −3.134 −23.758 −1.643 1.00 22.95 A ATOM 360 N LEU A 648 −1.913 −22.977 −3.376 1.00 22.24 A ATOM 361 CA LEU A 648 −3.010 −22.935 −4.323 1.00 22.62 A ATOM 362 CB LEU A 648 −3.302 −21.488 −4.743 1.00 22.09 A ATOM 363 CG LEU A 648 −4.285 −21.306 −5.898 1.00 21.11 A ATOM 364 CD1 LEU A 648 −5.639 −21.893 −5.505 1.00 22.47 A ATOM 365 CD2 LEU A 648 −4.418 −19.834 −6.250 1.00 21.63 A ATOM 366 C LEU A 648 −2.565 −23.737 −5.532 1.00 24.96 A ATOM 367 O LEU A 648 −1.525 −23.447 −6.131 1.00 25.51 A ATOM 368 N LYS A 649 −3.343 −24.755 −5.879 1.00 27.46 A ATOM 369 CA LYS A 649 −3.029 −25.596 −7.024 1.00 31.13 A ATOM 370 CB LYS A 649 −2.997 −27.078 −6.610 1.00 31.15 A ATOM 371 CG LYS A 649 −2.185 −27.994 −7.529 0.00 31.95 A ATOM 372 CD LYS A 649 −2.818 −28.177 −8.903 0.00 32.48 A ATOM 373 CE LYS A 649 −1.940 −29.047 −9.801 0.00 32.88 A ATOM 374 NZ LYS A 649 −1.650 −30.379 −9.199 0.00 33.21 A ATOM 375 C LYS A 649 −4.115 −25.373 −8.066 1.00 33.65 A ATOM 376 O LYS A 649 −5.272 −25.744 −7.858 1.00 35.71 A ATOM 377 N LEU A 650 −3.740 −24.753 −9.178 1.00 35.03 A ATOM 378 CA LEU A 650 −4.681 −24.498 −10.265 1.00 36.97 A ATOM 379 CB LEU A 650 −4.654 −23.021 −10.659 1.00 36.46 A ATOM 380 CG LEU A 650 −5.111 −22.027 −9.592 1.00 37.31 A ATOM 381 CD1 LEU A 650 −4.809 −20.616 −10.058 1.00 37.80 A ATOM 382 CD2 LEU A 650 −6.596 −22.211 −9.307 1.00 35.30 A ATOM 383 C LEU A 650 −4.308 −25.361 −11.465 1.00 36.94 A ATOM 384 O LEU A 650 −3.274 −26.027 −11.458 1.00 35.61 A ATOM 385 N ARG A 654 1.042 −25.384 −11.878 1.00 38.79 A ATOM 386 CA ARG A 654 1.946 −25.673 −10.770 1.00 38.06 A ATOM 387 CB ARG A 654 3.360 −25.184 −11.092 1.00 40.05 A ATOM 388 CG ARG A 654 4.377 −25.516 −10.010 0.00 40.81 A ATOM 389 CD ARG A 654 5.712 −24.843 −10.271 0.00 41.95 A ATOM 390 NE ARG A 654 6.674 −25.111 −9.205 0.00 42.83 A ATOM 391 CZ ARG A 654 7.878 −24.553 −9.127 0.00 43.31 A ATOM 392 NH1 ARG A 654 8.273 −23.692 −10.055 0.00 43.60 A ATOM 393 NH2 ARG A 654 8.687 −24.854 −8.121 0.00 43.60 A ATOM 394 C ARG A 654 1.477 −25.019 −9.473 1.00 36.96 A ATOM 395 O ARG A 654 0.953 −23.905 −9.479 1.00 37.48 A ATOM 396 N GLU A 655 1.677 −25.718 −8.360 1.00 34.47 A ATOM 397 CA GLU A 655 1.279 −25.210 −7.055 1.00 32.62 A ATOM 398 CB GLU A 655 1.489 −26.287 −5.995 1.00 34.16 A ATOM 399 CG GLU A 655 0.948 −25.913 −4.628 1.00 37.34 A ATOM 400 CD GLU A 655 1.042 −27.056 −3.638 1.00 39.34 A ATOM 401 OE1 GLU A 655 2.177 −27.464 −3.306 1.00 40.30 A ATOM 402 OE2 GLU A 655 −0.017 −27.547 −3.200 1.00 40.82 A ATOM 403 C GLU A 655 2.075 −23.963 −6.672 1.00 30.39 A ATOM 404 O GLU A 655 3.263 −23.864 −6.970 1.00 30.59 A ATOM 405 N ILE A 656 1.417 −23.006 −6.024 1.00 26.58 A ATOM 406 CA ILE A 656 2.096 −21.787 −5.599 1.00 24.21 A ATOM 407 CB ILE A 656 1.779 −20.575 −6.522 1.00 22.73 A ATOM 408 CG2 ILE A 656 2.273 −20.843 −7.949 1.00 21.90 A ATOM 409 CG1 ILE A 656 0.271 −20.283 −6.494 1.00 22.82 A ATOM 410 CD1 ILE A 656 −0.124 −18.937 −7.096 1.00 20.25 A ATOM 411 C ILE A 656 1.680 −21.399 −4.185 1.00 22.57 A ATOM 412 O ILE A 656 0.593 −21.758 −3.731 1.00 21.28 A ATOM 413 N PHE A 657 2.552 −20.669 −3.493 1.00 22.56 A ATOM 414 CA PHE A 657 2.251 −20.190 −2.147 1.00 21.07 A ATOM 415 CB PHE A 657 3.516 −19.648 −1.462 1.00 27.21 A ATOM 416 CG PHE A 657 4.424 −20.719 −0.909 1.00 32.40 A ATOM 417 CD1 PHE A 657 5.499 −21.203 −1.652 1.00 36.01 A ATOM 418 CD2 PHE A 657 4.188 −21.258 0.355 1.00 35.51 A ATOM 419 CE1 PHE A 657 6.327 −22.209 −1.144 1.00 36.52 A ATOM 420 CE2 PHE A 657 5.009 −22.265 0.872 1.00 37.58 A ATOM 421 CZ PHE A 657 6.080 −22.740 0.120 1.00 37.93 A ATOM 422 C PHE A 657 1.240 −19.054 −2.292 1.00 20.47 A ATOM 423 O PHE A 657 1.295 −18.298 −3.261 1.00 19.30 A ATOM 424 N VAL A 658 0.314 −18.941 −1.347 1.00 17.78 A ATOM 425 CA VAL A 658 −0.676 −17.873 −1.392 1.00 16.97 A ATOM 426 CB VAL A 658 −2.004 −18.311 −2.112 1.00 15.03 A ATOM 427 CG1 VAL A 658 −1.779 −18.443 −3.615 1.00 13.58 A ATOM 428 CG2 VAL A 658 −2.504 −19.636 −1.546 1.00 17.13 A ATOM 429 C VAL A 658 −1.034 −17.421 0.012 1.00 17.80 A ATOM 430 O VAL A 658 −0.782 −18.140 0.990 1.00 16.73 A ATOM 431 N ALA A 659 −1.596 −16.218 0.102 1.00 14.11 A ATOM 432 CA ALA A 659 −2.060 −15.671 1.367 1.00 15.67 A ATOM 433 CB ALA A 659 −1.810 −14.162 1.433 1.00 14.67 A ATOM 434 C ALA A 659 −3.552 −15.965 1.283 1.00 16.07 A ATOM 435 O ALA A 659 −4.150 −15.830 0.207 1.00 16.48 A ATOM 436 N ILE A 660 −4.145 −16.377 2.401 1.00 17.28 A ATOM 437 CA ILE A 660 −5.557 −16.756 2.453 1.00 20.16 A ATOM 438 CB ILE A 660 −5.691 −18.307 2.608 1.00 20.13 A ATOM 439 CG2 ILE A 660 −7.149 −18.725 2.565 1.00 22.79 A ATOM 440 CG1 ILE A 660 −4.938 −19.019 1.483 1.00 21.87 A ATOM 441 CD1 ILE A 660 −4.887 −20.538 1.654 1.00 22.50 A ATOM 442 C ILE A 660 −6.309 −16.101 3.609 1.00 22.05 A ATOM 443 O ILE A 660 −5.937 −16.254 4.774 1.00 22.45 A ATOM 444 N LYS A 661 −7.367 −15.372 3.274 1.00 22.33 A ATOM 445 CA LYS A 661 −8.201 −14.707 4.267 1.00 23.44 A ATOM 446 CB LYS A 661 −8.507 −13.270 3.850 1.00 26.63 A ATOM 447 CG LYS A 661 −7.426 −12.272 4.175 1.00 30.21 A ATOM 448 CD LYS A 661 −7.924 −10.863 3.894 1.00 32.40 A ATOM 449 CE LYS A 661 −6.980 −9.824 4.450 1.00 34.22 A ATOM 450 NZ LYS A 661 −7.561 −8.466 4.315 1.00 34.03 A ATOM 451 C LYS A 661 −9.509 −15.479 4.376 1.00 23.79 A ATOM 452 O LYS A 661 −10.109 −15.837 3.366 1.00 22.44 A ATOM 453 N THR A 662 −9.940 −15.751 5.599 1.00 22.77 A ATOM 454 CA THR A 662 −11.174 −16.485 5.800 1.00 23.53 A ATOM 455 CB THR A 662 −10.938 −17.758 6.637 1.00 25.15 A ATOM 456 OG1 THR A 662 −10.286 −17.399 7.860 1.00 26.34 A ATOM 457 CG2 THR A 662 −10.065 −18.748 5.872 1.00 25.34 A ATOM 458 C THR A 662 −12.183 −15.608 6.518 1.00 24.19 A ATOM 459 O THR A 662 −11.814 −14.694 7.256 1.00 25.54 A ATOM 460 N LEU A 663 −13.459 −15.887 6.282 1.00 24.00 A ATOM 461 CA LEU A 663 −14.542 −15.146 6.904 1.00 26.09 A ATOM 462 CB LEU A 663 −15.667 −14.907 5.887 1.00 23.14 A ATOM 463 CG LEU A 663 −16.886 −14.132 6.383 1.00 24.98 A ATOM 464 CD1 LEU A 663 −16.448 −12.756 6.855 1.00 22.54 A ATOM 465 CD2 LEU A 663 −17.931 −14.012 5.263 1.00 23.69 A ATOM 466 C LEU A 663 −15.067 −15.977 8.076 1.00 27.30 A ATOM 467 O LEU A 663 −15.493 −17.115 7.888 1.00 28.82 A ATOM 468 N LYS A 664 −15.026 −15.401 9.275 1.00 28.84 A ATOM 469 CA LYS A 664 −15.490 −16.061 10.490 1.00 30.02 A ATOM 470 CB LYS A 664 −15.417 −15.086 11.674 1.00 31.14 A ATOM 471 CG LYS A 664 −16.325 −13.865 11.549 0.00 31.57 A ATOM 472 CD LYS A 664 −16.193 −12.935 12.752 0.00 32.18 A ATOM 473 CE LYS A 664 −17.158 −11.760 12.657 0.00 32.50 A ATOM 474 NZ LYS A 664 −16.945 −10.972 11.413 0.00 32.80 A ATOM 475 C LYS A 664 −16.923 −16.572 10.334 1.00 30.86 A ATOM 476 O LYS A 664 −17.802 −15.841 9.880 1.00 31.20 A ATOM 477 N SER A 665 −17.152 −17.829 10.711 1.00 31.16 A ATOM 478 CA SER A 665 −18.479 −18.439 10.628 1.00 30.42 A ATOM 479 CB SER A 665 −18.431 −19.861 11.178 1.00 32.90 A ATOM 480 OG SER A 665 −18.013 −19.840 12.532 1.00 35.02 A ATOM 481 C SER A 665 −19.487 −17.629 11.439 1.00 30.07 A ATOM 482 O SER A 665 −19.128 −17.026 12.455 1.00 29.38 A ATOM 483 N GLY A 666 −20.743 −17.622 10.993 1.00 28.66 A ATOM 484 CA GLY A 666 −21.781 −16.876 11.689 1.00 27.97 A ATOM 485 C GLY A 666 −21.789 −15.423 11.250 1.00 27.26 A ATOM 486 O GLY A 666 −22.273 −14.535 11.958 1.00 25.74 A ATOM 487 N TYR A 667 −21.239 −15.186 10.065 1.00 27.08 A ATOM 488 CA TYR A 667 −21.156 −13.847 9.494 1.00 25.72 A ATOM 489 CB TYR A 667 −20.169 −13.854 8.325 1.00 25.23 A ATOM 490 CG TYR A 667 −20.563 −14.793 7.207 1.00 24.76 A ATOM 491 CD1 TYR A 667 −21.567 −14.447 6.301 1.00 23.91 A ATOM 492 CR1 TYR A 667 −21.951 −15.314 5.284 1.00 25.60 A ATOM 493 CD2 TYR A 667 −19.947 −16.040 7.067 1.00 23.97 A ATOM 494 CE2 TYR A 667 −20.323 −16.917 6.051 1.00 25.46 A ATOM 495 CZ TYR A 667 −21.325 −16.546 5.163 1.00 26.43 A ATOM 496 OH TYR A 667 −21.691 −17.392 4.143 1.00 28.78 A ATOM 497 C TYR A 667 −22.515 −13.345 9.004 1.00 25.35 A ATOM 498 O TYR A 667 −23.358 −14.125 8.569 1.00 24.49 A ATOM 499 N THR A 668 −22.720 −12.037 9.081 1.00 24.59 A ATOM 500 CA THR A 668 −23.963 −11.444 8.612 1.00 24.16 A ATOM 501 CB THR A 668 −24.265 −10.131 9.344 1.00 25.06 A ATOM 502 OG1 THR A 668 −23.182 −9.209 9.132 1.00 28.51 A ATOM 503 CG2 THR A 668 −24.432 −10.381 10.837 1.00 24.37 A ATOM 504 C THR A 668 −23.801 −11.147 7.119 1.00 24.62 A ATOM 505 O THR A 668 −22.689 −11.224 6.585 1.00 21.64 A ATOM 506 N GLU A 669 −24.908 −10.809 6.459 1.00 22.42 A ATOM 507 CA GLU A 669 −24.901 −10.493 5.031 1.00 23.71 A ATOM 508 CB GLU A 669 −26.315 −10.102 4.578 1.00 24.53 A ATOM 509 CG GLU A 669 −26.450 −9.796 3.099 0.00 25.34 A ATOM 510 CD GLU A 669 −26.084 −10.978 2.226 0.00 25.88 A ATOM 511 OE1 GLU A 669 −26.743 −12.033 2.345 0.00 26.22 A ATOM 512 0E2 GLU A 669 −25.137 −10.853 1.422 0.00 26.22 A ATOM 513 C GLU A 669 −23.926 −9.351 4.744 1.00 21.59 A ATOM 514 O GLU A 669 −23.152 −9.408 3.797 1.00 23.09 A ATOM 515 N LYS A 670 −23.956 −8.329 5.589 1.00 22.19 A ATOM 516 CA LYS A 670 −23.092 −7.171 5.439 1.00 20.44 A ATOM 517 CB LYS A 670 −23.522 −6.073 6.415 1.00 19.94 A ATOM 518 CG LYS A 670 −22.615 −4.846 6.417 1.00 19.99 A ATOM 519 CD LYS A 670 −23.150 −3.762 7.315 1.00 19.07 A ATOM 520 CE LYS A 670 −22.130 −2.654 7.524 1.00 21.46 A ATOM 521 NZ LYS A 670 −21.542 −2.169 6.255 1.00 21.44 A ATOM 522 C LYS A 670 −21.622 −7.527 5.668 1.00 22.01 A ATOM 523 O LYS A 670 −20.750 −7.100 4.913 1.00 18.77 A ATOM 524 N GLN A 671 −21.339 −8.305 6.707 1.00 20.25 A ATOM 525 CA GLN A 671 −19.957 −8.678 6.969 1.00 21.57 A ATOM 526 CB GLN A 671 −19.857 −9.540 8.226 1.00 19.59 A ATOM 527 CG GLN A 671 −20.174 −8.772 9.489 1.00 23.04 A ATOM 528 CD GLN A 671 −20.090 −9.646 10.715 1.00 23.12 A ATOM 529 OE1 GLN A 671 −20.591 −10.765 10.716 1.00 25.03 A ATOM 530 NE2 GLN A 671 −19.454 −9.141 11.766 1.00 26.08 A ATOM 531 C GLN A 671 −19.360 −9.412 5.774 1.00 19.09 A ATOM 532 O GLN A 671 −18.203 −9.188 5.419 1.00 19.45 A ATOM 533 N ARG A 672 −20.159 −10.263 5.143 1.00 17.49 A ATOM 534 CA ARG A 672 −19.711 −11.014 3.978 1.00 18.83 A ATOM 535 CB ARG A 672 −20.775 −12.044 3.584 1.00 18.14 A ATOM 536 CG ARG A 672 −20.482 −12.799 2.295 1.00 19.76 A ATOM 537 CD ARG A 672 −21.620 −13.754 1.961 1.00 21.40 A ATOM 538 NE ARG A 672 −21.459 −14.337 0.633 1.00 23.81 A ATOM 539 CZ ARG A 672 −21.574 −13.656 −0.506 1.00 23.75 A ATOM 540 NH1 ARG A 672 −21.863 −12.361 −0.486 1.00 24.13 A ATOM 541 NH2 ARG A 672 −21.377 −14.267 −1.665 1.00 23.85 A ATOM 542 C ARG A 672 −19.461 −10.053 2.813 1.00 19.29 A ATOM 543 O AEG A 672 −18.476 −10.172 2.080 1.00 17.76 A ATOM 544 N ARG A 673 −20.376 −9.102 2.655 1.00 19.04 A ATOM 545 CA ARG A 673 −20.280 −8.113 1.592 1.00 18.53 A ATOM 546 CB ARG A 673 −21.499 −7.192 1.599 1.00 16.97 A ATOM 547 CG ARG A 673 −21.472 −6.171 0.481 1.00 16.95 A ATOM 548 CD ARG A 673 −22.763 −5.428 0.403 1.00 18.42 A ATOM 549 NE ARG A 673 −22.963 −4.625 1.595 1.00 23.56 A ATOM 550 CZ ARG A 673 −24.042 −4.692 2.366 1.00 20.84 A ATOM 551 NE1 ARG A 673 −25.022 −5.533 2.066 1.00 22.79 A ATOM 552 NH2 ARG A 673 −24.140 −3.912 3.434 1.00 21.92 A ATOM 553 C ARG A 673 −19.028 −7.269 1.740 1.00 17.35 A ATOM 554 O ARG A 673 −18.245 −7.137 0.802 1.00 18.98 A ATOM 555 N ASP A 674 −18.852 −6.678 2.915 1.00 15.56 A ATOM 556 CA ASP A 674 −17.690 −5.846 3.151 1.00 17.33 A ATOM 557 CB ASP A 674 −17.810 −5.182 4.527 1.00 18.55 A ATOM 558 CG ASP A 674 −19.012 −4.227 4.609 1.00 22.12 A ATOM 559 OD1 ASP A 674 −19.522 −3.825 3.542 1.00 19.41 A ATOM 560 OD2 ASP A 674 −19.441 −3.870 5.722 1.00 23.46 A ATOM 561 C ASP A 674 −16.376 −6.635 2.991 1.00 16.55 A ATOM 562 O ASP A 674 −15.400 −6.145 2.412 1.00 14.92 A ATOM 563 N PHE A 675 −16.362 −7.864 3.476 1.00 14.43 A ATOM 564 CA PHE A 675 −15.190 −8.711 3.345 1.00 15.13 A ATOM 565 CB PHE A 675 −15.483 −10.070 3.969 1.00 14.23 A ATOM 566 CG PHE A 675 −14.376 −11.054 3.821 1.00 14.93 A ATOM 567 CD1 PHE A 675 −13.181 −10.873 4.501 1.00 17.64 A ATOM 568 CD2 PHE A 675 −14.543 −12.188 3.040 1.00 16.15 A ATOM 569 CE1 PHE A 675 −12.164 −11.815 4.414 1.00 17.02 A ATOM 570 CE2 PHE A 675 −13.536 −13.135 2.944 1.00 19.09 A ATOM 571 CZ PHE A 675 −12.342 −12.949 3.636 1.00 18.72 A ATOM 572 C PHE A 675 −14.812 −8.912 1.873 1.00 14.71 A ATOM 573 O PHE A 675 −13.672 −8.655 1.464 1.00 13.96 A ATOM 574 N LEU A 676 −15.780 −9.363 1.080 1.00 13.97 A ATOM 575 CA LEU A 676 −15.550 −9.638 −0.331 1.00 12.30 A ATOM 576 CB LEU A 676 −16.721 −10.465 −0.913 1.00 13.83 A ATOM 577 CG LEU A 676 −16.885 −11.904 −0.364 1.00 13.35 A ATOM 578 CD1 LEU A 676 −18.132 −12.553 −0.923 1.00 14.68 A ATOM 579 CD2 LEU A 676 −15.665 −12.732 −0.726 1.00 14.56 A ATOM 580 C LEU A 676 −15.318 −8.387 −1.172 1.00 12.89 A ATOM 581 O LEU A 676 −14.816 −8.488 −2.292 1.00 14.97 A ATOM 582 N SER A 677 −15.663 −7.212 −0.651 1.00 11.83 A ATOM 583 CA SER A 677 −15.448 −5.999 −1.438 1.00 14.06 A ATOM 584 CB SER A 677 −16.016 −4.758 −0.733 1.00 12.26 A ATOM 585 OG SER A 677 −15.253 −4.398 0.404 1.00 15.09 A ATOM 586 C SER A 677 −13.952 −5.848 −1.665 1.00 14.36 A ATOM 587 O SER A 677 −13.524 −5.330 −2.685 1.00 14.36 A ATOM 588 N GLU A 678 −13.144 −6.304 −0.715 1.00 16.37 A ATOM 589 CA GLU A 678 −11.705 −6.200 −0.916 1.00 15.57 A ATOM 590 CB GLU A 678 −10.946 −6.832 0.246 1.00 19.69 A ATOM 591 CG GLU A 678 −9.443 −6.939 −0.008 1.00 24.61 A ATOM 592 CD GLU A 678 −8.694 −7.521 1.166 1.00 27.65 A ATOM 593 OE1 GLU A 678 −9.219 −8.448 1.807 1.00 29.80 A ATOM 594 OE2 GLU A 678 −7.571 −7.052 1.440 1.00 32.17 A ATOM 595 CG GLU A 678 −11.328 −6.885 −2.240 1.00 14.92 A ATOM 596 O GLU A 678 −10.498 −6.386 −2.996 1.00 16.05 A ATOM 597 N ALA A 679 −11.958 −8.015 −2.532 1.00 12.66 A ATOM 598 CA ALA A 679 −11.659 −8.737 −3.761 1.00 13.34 A ATOM 599 CB ALA A 679 −12.111 −10.186 −3.650 1.00 9.98 A ATOM 600 C ALA A 679 −12.296 −8.084 −4.981 1.00 13.80 A ATOM 601 O ALA A 679 −11.699 −8.078 −6.059 1.00 12.31 A ATOM 602 N SER A 680 −13.503 −7.544 −4.829 1.00 14.31 A ATOM 603 CA SER A 680 −14.156 −6.915 −5.975 1.00 14.70 A ATOM 604 CB SER A 680 −15.637 −6.606 −5.666 1.00 13.71 A ATOM 605 OG SER A 680 −15.802 −5.683 −4.610 1.00 19.60 A ATOM 606 C SER A 680 −13.369 −5.665 −6.365 1.00 15.81 A ATOM 607 O SER A 680 −13.449 −5.192 −7.496 1.00 17.05 A ATOM 608 N ILE A 681 −12.566 −5.160 −5.431 1.00 15.14 A ATOM 609 CA ILE A 681 −11.739 −3.998 −5.695 1.00 14.43 A ATOM 610 CB ILE A 681 −11.583 −3.167 −4.412 1.00 15.35 A ATOM 611 CG2 ILE A 681 −10.483 −2.107 −4.589 1.00 13.45 A ATOM 612 CG1 ILE A 681 −12.955 −2.582 −4.050 1.00 12.39 A ATOM 613 CD1 ILE A 681 −12.965 −1.725 −2.820 1.00 13.10 A ATOM 614 C ILE A 681 −10.382 −4.441 −6.241 1.00 15.72 A ATOM 615 O ILE A 681 −10.014 −4.091 −7.371 1.00 15.31 A ATOM 616 N MET A 682 −9.658 −5.247 −5.465 1.00 14.71 A ATOM 617 CA MET A 682 −8.349 −5.746 −5.871 1.00 14.74 A ATOM 618 CE MET A 682 −7.862 −6.775 −4.835 1.00 15.19 A ATOM 619 CG MET A 682 −6.417 −7.225 −5.012 1.00 17.99 A ATOM 620 SD MET A 682 −5.958 −8.505 −3.763 1.00 18.16 A ATOM 621 CE MET A 682 −6.407 −7.626 −2.305 1.00 8.10 A ATOM 622 C MET A 682 −8.384 −6.381 −7.267 1.00 13.42 A ATOM 623 O MET A 682 −7.472 −6.179 −8.076 1.00 12.39 A ATOM 624 N GLY A 683 −9.463 −7.108 −7.563 1.00 11.77 A ATOM 625 CA GLY A 683 −9.598 −7.780 −8.856 1.00 10.35 A ATOM 626 C GLY A 683 −9.632 −6.903 −10.105 1.00 11.65 A ATOM 627 O GLY A 683 −9.492 −7.388 −11.229 1.00 10.47 A ATOM 628 N GLN A 684 −9.816 −5.607 −9.911 1.00 11.57 A ATOM 629 CA GLN A 684 −9.862 −4.670 −11.032 1.00 13.82 A ATOM 630 CE GLN A 684 −10.759 −3.487 −10.680 1.00 14.52 A ATOM 631 CG GLN A 684 −12.201 −3.851 −10.377 1.00 13.27 A ATOM 632 CD GLN A 684 −13.003 −2.641 −9.965 1.00 13.03 A ATOM 633 OE1 GLN A 684 −12.961 −1.601 −10.637 1.00 14.53 A ATOM 634 NE2 GLN A 684 −13.730 −2.754 −8.857 1.00 9.41 A ATOM 635 C GLN A 684 −8.475 −4.129 −11.345 1.00 14.70 A ATOM 636 O GLN A 684 −8.274 −3.438 −12.347 1.00 13.46 A ATOM 637 N PHE A 685 −7.521 −4.425 −10.469 1.00 14.39 A ATOM 638 CA PHE A 685 −6.156 −3.925 −10.639 1.00 14.62 A ATOM 639 CE PHE A 685 −5.644 −3.368 −9.313 1.00 13.37 A ATOM 640 CG PHE A 685 −6.545 −2.344 −8.696 1.00 13.64 A ATOM 641 CD1 PHE A 685 −6.742 −2.327 −7.318 1.00 10.36 A ATOM 642 CD2 PHE A 685 −7.187 −1.385 −9.483 1.00 12.29 A ATOM 643 CE1 PHE A 685 −7.573 −1.361 −6.724 1.00 12.32 A ATOM 644 CE2 PHE A 685 −8.016 −0.419 −8.899 1.00 11.59 A ATOM 645 CE PHE A 685 −8.210 −0.406 −7.520 1.00 13.91 A ATOM 646 C PHE A 685 −5.187 −4.968 −11.146 1.00 14.76 A ATOM 647 O PHE A 685 −5.306 −6.144 −10.836 1.00 15.69 A ATOM 648 N ASP A 686 −4.231 −4.531 −11.952 1.00 15.75 A ATOM 649 CA ASP A 686 −3.230 −5.441 −12.477 1.00 16.52 A ATOM 650 CB ASP A 686 −3.648 −6.006 −13.833 1.00 17.91 A ATOM 651 CG ASP A 686 −2.696 −7.075 −14.319 1.00 20.72 A ATOM 652 OD1 ASP A 686 −2.813 −7.517 −15.481 1.00 22.99 A ATOM 653 OD2 ASP A 686 −1.820 −7.480 −13.526 1.00 21.44 A ATOM 654 C ASP A 686 −1.929 −4.668 −12.626 1.00 16.22 A ATOM 655 O ASP A 686 −1.645 −4.100 −13.681 1.00 13.75 A ATOM 656 N HIS A 687 −1.143 −4.636 −11.557 1.00 15.08 A ATOM 657 CA HIS A 687 0.114 −3.912 −11.585 1.00 14.22 A ATOM 658 CB HIS A 687 −0.119 −2.460 −11.160 1.00 13.14 A ATOM 659 CG HIS A 687 1.084 −1.585 −11.315 1.00 16.93 A ATOM 660 CD2 HIS A 687 1.406 −0.672 −12.264 1.00 15.49 A ATOM 661 HD1 HIS A 687 2.141 −1.610 −10.431 1.00 15.21 A ATOM 662 CE1 HIS A 687 3.062 −0.748 −10.828 1.00 17.79 A ATOM 663 NE2 HIS A 687 2.639 −0.166 −11.937 1.00 16.56 A ATOM 664 C HIS A 687 1.120 −4.598 −10.671 1.00 14.95 A ATOM 665 O HIS A 687 0.766 −5.125 −9.617 1.00 13.04 A ATOM 666 N PRO A 688 2.394 −4.612 −11.076 1.00 15.37 A ATOM 667 CD PRO A 688 2.933 −4.106 −12.355 1.00 13.76 A ATOM 668 CA PRO A 688 3.441 −5.250 −10.275 1.00 14.14 A ATOM 669 CB PRO A 688 4.716 −4.909 −11.048 1.00 16.35 A ATOM 670 CG PRO A 688 4.244 −4.857 −12.483 1.00 16.48 A ATOM 671 C PRO A 688 3.496 −4.785 −8.816 1.00 14.10 A ATOM 672 O PRO A 688 3.868 −5.558 −7.936 1.00 15.51 A ATOM 673 N ASN A 689 3.107 −3.543 −8.545 1.00 12.52 A ATOM 674 CA ASN A 689 3.171 −3.048 −7.173 1.00 12.26 A ATOM 675 CB ASN A 689 3.949 −1.741 −7.144 1.00 11.33 A ATOM 676 CG ASN A 689 5.370 −1.919 −7.629 1.00 13.08 A ATOM 677 OD1 ASN A 689 6.237 −2.433 −6.907 1.00 14.93 A ATOM 678 ND2 ASN A 689 5.618 −1.524 −8.864 1.00 10.50 A ATOM 679 C ASN A 689 1.840 −2.910 −6.458 1.00 9.30 A ATOM 680 O ASN A 689 1.685 −2.116 −5.543 1.00 9.38 A ATOM 681 N VAL A 690 0.872 −3.696 −6.901 1.00 10.15 A ATOM 682 CA VAL A 690 −0.438 −3.738 −6.275 1.00 10.17 A ATOM 683 CB VAL A 690 −1.523 −3.159 −7.189 1.00 11.34 A ATOM 684 CG1 VAL A 690 −2.907 −3.458 −6.593 1.00 5.73 A ATOM 685 CG2 VAL A 690 −1.320 −1.643 −7.296 1.00 8.17 A ATOM 686 C VAL A 690 −0.655 −5.232 −6.053 1.00 10.12 A ATOM 687 O VAL A 690 −0.445 −6.038 −6.959 1.00 10.79 A ATOM 688 N ILE A 691 −1.030 −5.601 −4.835 1.00 12.68 A ATOM 689 CA ILE A 691 −1.225 −7.005 −4.482 1.00 12.48 A ATOM 690 CB ILE A 691 −1.833 −7.136 −3.061 1.00 15.22 A ATOM 691 CG2 ILE A 691 −2.079 −8.597 −2.729 1.00 17.18 A ATOM 692 CG1 ILE A 691 −0.876 −6.555 −2.027 1.00 18.01 A ATOM 693 CD1 ILE A 691 0.426 −7.349 −1.935 1.00 24.97 A ATOM 694 C ILE A 691 −2.122 −7.724 −5.478 1.00 14.49 A ATOM 695 O ILE A 691 −3.213 −7.256 −5.798 1.00 14.87 A ATOM 696 N HIS A 692 −1.662 −8.877 −5.948 1.00 14.15 A ATOM 697 CA HIS A 692 −2.409 −9.658 −6.922 1.00 14.37 A ATOM 698 CB HIS A 692 −1.444 −10.529 −7.729 1.00 17.27 A ATOM 699 CG HIS A 692 −2.113 −11.404 −8.745 1.00 19.90 A ATOM 700 CD2 HIS A 692 −2.301 −12.743 −8.775 1.00 19.49 A ATOM 701 ND1 HIS A 692 −2.671 −10.913 −9.909 1.00 21.64 A ATOM 702 CE1 HIS A 692 −3.172 −11.914 −10.610 1.00 20.32 A ATOM 703 NE2 HIS A 692 −2.961 −13.035 −9.944 1.00 21.85 A ATOM 704 C HIS A 692 −3.472 −10.542 −6.286 1.00 14.88 K ATOM 705 O HIS A 692 −3.212 −11.229 −5.294 1.00 14.72 A ATOM 706 N LEU A 693 −4.673 −10.513 −6.854 1.00 11.54 A ATOM 707 CA LEU A 693 −5.759 −11.355 −6.369 1.00 11.27 A ATOM 708 CB LEU A 693 −7.113 −10.655 −6.518 1.00 11.71 A ATOM 709 CG LEU A 693 −8.362 −11.527 −6.311 1.00 12.06 A ATOM 710 CD1 LEU A 693 −8.584 −11.777 −4.808 1.00 13.97 A ATOM 711 CD2 LEU A 693 −9.568 −10.827 −6.903 1.00 12.36 A ATOM 712 C LEU A 693 −5.766 −12.629 −7.202 1.00 12.80 A ATOM 713 O LEU A 693 −5.744 −12.569 −8.432 1.00 12.66 A ATOM 714 N GLU A 694 −5.749 −13.784 −6.541 1.00 9.91 A ATOM 715 CA GLU A 694 −5.803 −15.043 −7.275 1.00 12.11 A ATOM 716 CB GLU A 694 −5.190 −16.197 −6.463 1.00 12.53 A ATOM 717 CG GLU A 694 −3.663 −16.209 −6.417 1.00 15.99 A ATOM 718 CD GLU A 694 −3.024 −16.390 −7.786 1.00 19.23 A ATOM 719 OE1 GLU A 694 −3.596 −17.118 −8.633 1.00 22.30 A ATOM 720 OE2 GLU A 694 −1.939 −15.817 −8.019 1.00 21.66 A ATOM 721 C GLU A 694 −7.284 −15.311 −7.497 1.00 12.27 A ATOM 722 O GLU A 694 −7.706 −15.664 −8.589 1.00 14.65 A ATOM 723 N GLY A 695 −8.072 −15.126 −6.446 1.00 12.00 A ATOM 724 CA GLY A 695 −9.501 −15.363 −6.554 1.00 13.93 A ATOM 725 C GLY A 695 −10.162 −15.460 −5.191 1.00 14.27 A ATOM 726 O GLY A 695 −9.562 −15.139 −4.165 1.00 15.08 A ATOM 727 N VAL A 696 −11.407 −15.914 −5.185 1.00 16.25 A ATOM 728 CA VAL A 696 −12.160 −16.051 −3.959 1.00 18.13 A ATOM 729 CB VAL A 696 −13.213 −14.920 −3.813 1.00 20.10 A ATOM 730 CG1 VAL A 696 −12.523 −13.577 −3.711 1.00 18.53 A ATOM 731 CG2 VAL A 696 −14.164 −14.947 −5.011 1.00 18.11 A ATOM 732 C VAL A 696 −12.900 −17.385 −3.944 1.00 20.73 A ATOM 733 O VAL A 696 −13.078 −18.040 −4.984 1.00 20.59 A ATOM 734 N VAL A 697 −13.324 −17.776 −2.752 1.00 20.83 A ATOM 735 CA VAL A 697 −14.086 −18.990 −2.564 1.00 22.28 A ATOM 736 CB VAL A 697 −13.365 −19.983 −1.621 1.00 24.02 A ATOM 737 CG1 VAL A 697 −14.184 −21.265 −1.499 1.00 22.46 A ATOM 738 CG2 VAL A 697 −11.960 −20.284 −2.156 1.00 22.98 A ATOM 739 C VAL A 697 −15.344 −18.486 −1.880 1.00 22.94 A ATOM 740 O VAL A 697 −15.268 −17.994 −0.758 1.00 22.04 A ATOM 741 N THR A 698 −16.484 −18.568 −2.568 1.00 25.19 A ATOM 742 CA THR A 698 −17.751 −18.113 −2.006 1.00 27.59 A ATOM 743 CB THR A 698 −18.298 −16.854 −2.736 1.00 25.83 A ATOM 744 OG1 THR A 698 −18.578 −17.176 −4.099 1.00 23.74 A ATOM 745 CG2 THR A 698 −17.287 −15.713 −2.687 1.00 24.82 A ATOM 746 C THR A 698 −18.828 −19.193 −2.076 1.00 31.39 A ATOM 747 O THR A 698 −19.826 −19.119 −1.362 1.00 32.32 A ATOM 748 N LYS A 699 −18.634 −20.186 −2.939 1.00 34.91 A ATOM 749 CA LYS A 699 −19.606 −21.265 −3.085 1.00 38.78 A ATOM 750 CB LYS A 699 −19.632 −21.763 −4.533 1.00 39.53 A ATOM 751 CG LYS A 699 −20.129 −20.728 −5.533 1.00 41.69 A ATOM 752 CD LYS A 699 −20.157 −21.281 −6.953 1.00 43.87 A ATOM 753 CE LYS A 699 −20.685 −20.252 −7.943 1.00 44.93 A ATOM 754 NZ LYS A 699 −20.775 −20.824 −9.328 1.00 47.77 A ATOM 755 C LYS A 699 −19.295 −22.422 −2.145 1.00 40.28 A ATOM 756 O LYS A 699 −19.761 −23.544 −2.342 1.00 42.43 A ATOM 757 N SER A 700 −18.505 −22.139 −1.117 1.00 41.32 A ATOM 758 CA SER A 700 −18.129 −23.146 −0.139 1.00 41.46 A ATOM 759 CE SER A 700 −16.927 −23.949 −0.642 1.00 41.67 A ATOM 760 OG SER A 700 −17.243 −24.643 −1.836 1.00 42.85 A ATOM 761 C SER A 700 −17.776 −22.463 1.176 1.00 41.64 A ATOM 762 O SER A 700 −17.550 −21.252 1.215 1.00 41.74 A ATOM 763 N THR A 701 −17.725 −23.250 2.246 1.00 40.19 A ATOM 764 CA THR A 701 −17.400 −22.745 3.575 1.00 40.36 A ATOM 765 CB THR A 701 −18.451 −23.208 4.618 1.00 41.83 A ATOM 766 OG1 THR A 701 −19.763 −22.837 4.175 1.00 44.63 A ATOM 767 CG2 THR A 701 −18.190 −22.558 5.973 1.00 42.59 A ATOM 768 C THR A 701 −16.024 −23.256 4.011 1.00 38.95 A ATOM 769 O THR A 701 −15.702 −24.434 3.844 1.00 39.42 A ATOM 770 N PRO A 702 −15.185 −22.370 4.565 1.00 37.14 A ATOM 771 CD PRO A 702 −13.936 −22.766 5.239 1.00 37.05 A ATOM 772 CA PRO A 702 −15.465 −20.949 4.792 1.00 34.67 A ATOM 773 CB PRO A 702 −14.551 −20.611 5.955 1.00 35.95 A ATOM 774 CG PRO A 702 −13.338 −21.429 5.630 1.00 36.79 A ATOM 775 C PRO A 702 −15.158 −20.095 3.569 1.00 31.84 A ATOM 776 O PRO A 702 −14.339 −20.469 2.734 1.00 31.01 A ATOM 777 N VAL A 703 −15.831 −18.952 3.472 1.00 30.06 A ATOM 778 CA VAL A 703 −15.620 −18.017 2.372 1.00 26.08 A ATOM 779 CB VAL A 703 −16.592 −16.830 2.475 1.00 27.78 A ATOM 780 CG1 VAL A 703 −16.399 −15.886 1.292 1.00 26.07 A ATOM 781 CG2 VAL A 703 −18.028 −17.343 2.525 1.00 27.11 A ATOM 782 C VAL A 703 −14.183 −17.510 2.493 1.00 23.65 A ATOM 783 O VAL A 703 −13.727 −17.199 3.591 1.00 22.73 A ATOM 784 N MET A 704 −13.480 −17.422 1.367 1.00 21.87 A ATOM 785 CA MET A 704 −12.091 −16.985 1.371 1.00 19.85 A ATOM 786 CE MET A 704 −11.154 −18.194 1.287 1.00 20.58 A ATOM 787 CG MET A 704 −11.394 −19.298 2.324 1.00 22.83 A ATOM 788 SD MET A 704 −10.199 −20.637 2.110 1.00 25.21 A ATOM 789 CE MET A 704 −11.006 −21.626 0.904 1.00 26.56 A ATOM 790 C MET A 704 −11.702 −16.055 0.226 1.00 18.73 A ATOM 791 O MET A 704 −12.348 −16.027 −0.817 1.00 18.27 A ATOM 792 N ILE A 705 −10.611 −15.327 0.446 1.00 16.10 A ATOM 793 CA ILE A 705 −10.020 −14.433 −0.541 1.00 14.53 A ATOM 794 CB ILE A 705 −10.033 −12.980 −0.079 1.00 14.98 A ATOM 795 CG2 ILE A 705 −9.219 −12.088 −1.066 1.00 13.23 A ATOM 796 CG1 ILE A 705 −11.473 −12.508 0.019 1.00 13.64 A ATOM 797 CD1 ILE A 705 −11.593 −11.116 0.560 1.00 15.61 A ATOM 798 C ILE A 705 −8.588 −14.917 −0.598 1.00 14.95 A ATOM 799 O ILE A 705 −7.921 −14.999 0.437 1.00 16.93 A ATOM 800 N ILE A 706 −8.125 −15.247 −1.797 1.00 14.61 A ATOM 801 CA ILE A 706 −6.776 −15.761 −1.995 1.00 14.22 A ATOM 802 CB ILE A 706 −6.799 −17.054 −2.837 1.00 13.99 A ATOM 803 CG2 ILE A 706 −5.448 −17.747 −2.748 1.00 15.86 A ATOM 804 CG1 ILE A 706 −7.914 −17.987 −2.353 1.00 16.58 A ATOM 805 CD1 ILE A 706 −7.755 −18.443 −0.919 1.00 23.47 A ATOM 806 C ILE A 706 −5.952 −14.726 −2.741 1.00 14.50 A ATOM 807 O ILE A 706 −6.346 −14.300 −3.829 1.00 12.53 A ATOM 808 N THR A 707 −4.806 −14.342 −2.179 1.00 12.32 A ATOM 809 CA THR A 707 −3.930 −13.344 −2.810 1.00 14.46 A ATOM 810 CB THR A 707 −3.926 −12.026 −2.005 1.00 16.58 A ATOM 811 OG1 TER A 707 −3.435 −12.288 −0.685 1.00 18.64 A ATOM 812 CG2 THR A 707 −5.334 −11.434 −1.895 1.00 15.55 A ATOM 813 C THR A 707 −2.486 −13.847 −2.921 1.00 16.08 A ATOM 814 O THR A 707 −2.153 −14.876 −2.337 1.00 15.13 A ATOM 815 N GLU A 708 −1.631 −13.150 3.673 1.00 14.63 A ATOM 816 CA GLU A 708 −0.240 −13.603 −3.798 1.00 16.45 A ATOM 817 CB GLU A 708 0.576 −12.730 −4.779 1.00 16.75 A ATOM 818 CG GLU A 708 0.855 −11.308 −4.315 1.00 17.77 A ATOM 819 CD GLU A 708 1.522 −10.440 −5.399 1.00 18.66 A ATOM 820 OE1 GLU A 708 0.897 −9.447 −5.806 1.00 17.59 A ATOM 821 OE2 GLU A 708 2.670 −10.747 −5.833 1.00 18.27 A ATOM 822 C GLU A 708 0.412 −13.574 −2.428 1.00 15.05 A ATOM 823 O GLU A 708 0.091 −12.730 −1.582 1.00 12.21 A ATOM 824 N PHE A 709 1.319 −14.516 −2.203 1.00 15.72 A ATOM 825 CA PHE A 709 2.001 −14.599 −0.920 1.00 16.73 A ATOM 826 CE PHE A 709 2.486 −16.035 −0.678 1.00 18.37 A ATOM 827 CG PHE A 709 3.127 −16.238 0.661 1.00 20.59 A ATOM 828 CD1 PHE A 709 2.423 −15.975 1.829 1.00 21.91 A ATOM 829 CD2 PHE A 709 4.433 −16.690 0.756 1.00 23.57 A ATOM 830 CE1 PHE A 709 3.011 −16.160 3.074 1.00 24.66 A ATOM 831 CE2 PHE A 709 5.031 −16.881 1.997 1.00 23.90 A ATOM 832 CZ PHE A 709 4.315 −16.614 3.160 1.00 25.45 A ATOM 833 C PHE A 709 3.178 −13.630 −0.890 1.00 15.59 A ATOM 834 O PHE A 709 3.928 −13.541 −1.853 1.00 16.82 A ATOM 835 N MET A 710 3.316 −12.906 0.219 1.00 14.56 A ATOM 836 CA MET A 710 4.393 −11.933 0.410 1.00 16.05 A ATOM 837 CB MET A 710 3.793 −10.539 0.610 1.00 15.84 A ATOM 838 CG MET A 710 2.896 −10.105 −0.547 1.00 16.83 A ATOM 839 SD MET A 710 3.759 −9.890 −2.108 1.00 16.56 A ATOM 840 CE MET A 710 4.355 −8.267 −1.864 1.00 17.49 A ATOM 841 C MET A 710 5.198 −12.365 1.642 1.00 15.49 A ATOM 842 O MET A 710 4.828 −12.075 2.774 1.00 13.99 A ATOM 843 N GLU A 711 6.301 −13.065 1.400 1.00 17.57 A ATOM 844 CA GLU A 711 7.130 −13.597 2.478 1.00 20.55 A ATOM 845 CB GLU A 711 8.369 −14.275 1.906 1.00 23.66 A ATOM 846 CG GLU A 711 8.052 −15.543 1.150 1.00 32.78 A ATOM 847 CD GLU A 711 9.241 −16.479 1.065 1.00 35.60 A ATOM 848 OE1 GLU A 711 9.088 −17.579 0.478 1.00 37.62 A ATOM 849 OE2 GLU A 711 10.319 −16.112 1.589 1.00 36.45 A ATOM 850 C GLU A 711 7.554 −12.624 3.551 1.00 20.06 A ATOM 851 O GLU A 711 7.577 −12.970 4.728 1.00 20.45 A ATOM 852 N ASN A 712 7.879 −11.403 3.165 1.00 16.84 A ATOM 853 CA ASN A 712 8.322 −10.459 4.160 1.00 15.71 A ATOM 854 CB ASN A 712 9.368 −9.544 3.547 1.00 17.27 A ATOM 855 CG ASN A 712 10.627 −10.303 3.222 1.00 17.78 A ATOM 856 OD1 ASN A 712 11.034 −11.157 4.005 1.00 16.07 A ATOM 857 ND2 ASN A 712 11.236 −10.026 2.081 1.00 18.84 A ATOM 858 C ASN A 712 7.237 −9.685 4.868 1.00 15.77 A ATOM 859 O ASN A 712 7.515 −8.845 5.711 1.00 13.23 A ATOM 860 N GLY A 713 5.991 −9.995 4.537 1.00 16.18 A ATOM 861 CA GLY A 713 4.884 −9.350 5.207 1.00 13.90 A ATOM 862 C GLY A 713 4.785 −7.846 5.109 1.00 14.53 A ATOM 863 O GLY A 713 5.179 −7.237 4.108 1.00 13.01 A ATOM 864 N SER A 714 4.258 −7.252 6.173 1.00 10.95 A ATOM 865 CA SER A 714 4.068 −5.822 6.231 1.00 15.09 A ATOM 866 CB SER A 714 3.195 −5.470 7.424 1.00 16.14 A ATOM 867 OG SER A 714 1.949 −6.125 7.292 1.00 17.72 A ATOM 868 C SER A 714 5.383 −5.075 6.288 1.00 15.86 A ATOM 869 O SER A 714 6.290 −5.427 7.041 1.00 12.51 A ATOM 870 N LEU A 715 5.457 −4.030 5.476 1.00 14.56 A ATOM 871 CA LEU A 715 6.639 −3.206 5.352 1.00 15.61 A ATOM 872 CB LEU A 715 6.399 −2.141 4.284 1.00 12.49 A ATOM 873 CG LEU A 715 7.574 −1.209 4.012 1.00 15.37 A ATOM 874 CD1 LEU A 715 8.786 −2.009 3.583 1.00 12.76 A ATOM 875 CD2 LEU A 715 7.161 −0.200 2.907 1.00 12.52 A ATOM 876 C LEU A 715 7.102 −2.540 6.637 1.00 14.75 A ATOM 877 O LEU A 715 8.300 −2.500 6.905 1.00 17.56 A ATOM 878 N ASP A 716 6.180 −2.018 7.444 1.00 15.82 A ATOM 879 CA ASP A 716 6.631 −1.369 8.674 1.00 17.28 A ATOM 880 CB ASP A 716 5.462 −0.652 9.389 1.00 16.92 A ATOM 881 CG ASP A 716 4.361 −1.603 9.849 1.00 19.44 A ATOM 882 OD1 ASP A 716 3.995 −2.546 9.109 1.00 17.35 A ATOM 883 OD2 ASP A 716 3.850 −1.389 10.964 1.00 22.24 A ATOM 884 C ASP A 716 7.317 −2.397 9.587 1.00 17.91 A ATOM 885 O ASP A 716 8.431 −2.169 10.059 1.00 16.46 A ATOM 886 N SER A 717 6.677 −3.542 9.802 1.00 17.08 A ATOM 887 CA SER A 717 7.266 −4.593 10.654 1.00 17.05 A ATOM 888 CB SER A 717 6.283 −5.747 10.807 1.00 18.18 A ATOM 889 OG SER A 717 5.131 −5.296 11.484 1.00 24.48 A ATOM 890 C SER A 717 8.568 −5.136 10.081 1.00 14.71 A ATOM 891 O SER A 717 9.537 −5.363 10.807 1.00 12.74 A ATOM 892 N PHE A 718 8.576 −5.340 8.766 1.00 13.61 A ATOM 893 CA PHE A 718 9.742 −5.854 8.061 1.00 11.92 A ATOM 894 CB PHE A 718 9.456 −5.913 6.566 1.00 12.48 A ATOM 895 CG PHE A 718 10.624 −6.331 5.736 1.00 12.92 A ATOM 896 CD1 PHE A 718 11.172 −7.605 5.873 1.00 13.91 A ATOM 897 CD2 PHE A 718 11.155 −5.465 4.780 1.00 13.01 A ATOM 898 CE1 PHE A 718 12.229 −8.021 5.069 1.00 14.75 A ATOM 899 CE2 PHE A 718 12.209 −5.864 3.969 1.00 10.87 A ATOM 900 CZ PHE A 718 12.752 −7.153 4.110 1.00 14.74 A ATOM 901 C PHE A 718 10.947 −4.968 8.294 1.00 12.69 A ATOM 902 O PHE A 718 12.044 −5.456 8.563 1.00 13.46 A ATOM 903 N LEU A 719 10.736 −3.662 8.176 1.00 13.46 A ATOM 904 CA LEU A 719 11.806 −2.698 8.358 1.00 16.37 A ATOM 905 CB LEU A 719 11.357 −1.299 7.923 1.00 14.77 A ATOM 906 CG LEU A 719 11.232 −1.091 6.407 1.00 18.77 A ATOM 907 CD1 LEU A 719 10.819 0.339 6.130 1.00 16.45 A ATOM 908 CD2 LEU A 719 12.556 −1.395 5.718 1.00 20.57 A ATOM 909 C LEU A 719 12.280 −2.655 9.797 1.00 14.90 A ATOM 910 O LEU A 719 13.465 −2.497 10.052 1.00 14.07 A ATOM 911 N ARG A 720 11.360 −2.792 10.742 1.00 16.00 A ATOM 912 CA ARG A 720 11.776 −2.759 12.137 1.00 16.42 A ATOM 913 CB ARG A 720 10.563 −2.702 13.062 1.00 18.72 A ATOM 914 CG ARG A 720 10.012 −1.296 13.208 1.00 19.57 A ATOM 915 CD ARG A 720 8.967 −1.164 14.300 1.00 22.51 A ATOM 916 NE ARG A 720 7.624 −1.499 13.843 1.00 28.80 A ATOM 917 CZ ARG A 720 7.146 −2.734 13.738 1.00 31.29 A ATOM 918 NH1 ARG A 720 7.902 −3.777 14.063 1.00 33.67 A ATOM 919 NH2 ARG A 720 5.903 −2.922 13.311 1.00 31.71 A ATOM 920 C ARG A 720 12.662 −3.951 12.463 1.00 17.27 A ATOM 921 O ARG A 720 13.634 −3.826 13.215 1.00 18.44 A ATOM 922 N GLN A 721 12.348 −5.098 11.870 1.00 16.09 A ATOM 923 CA GLN A 721 13.116 −6.313 12.107 1.00 18.82 A ATOM 924 CB GLN A 721 12.287 −7.532 11.709 1.00 20.62 A ATOM 925 CG GLN A 721 10.946 −7.586 12.403 1.00 25.99 A ATOM 926 CD GLN A 721 10.026 −8.623 11.801 1.00 29.22 A ATOM 927 OE1 GLN A 721 10.338 −9.231 10.768 1.00 31.08 A ATOM 928 NE2 GLN A 721 8.875 −8.827 12.435 1.00 30.60 A ATOM 929 C GLN A 721 14.426 −6.339 11.332 1.00 18.64 A ATOM 930 O GLN A 721 15.242 −7.261 11.481 1.00 17.28 A ATOM 931 N ASN A 722 14.619 −5.326 10.499 1.00 17.52 A ATOM 932 CA ASN A 722 15.813 −5.236 9.676 1.00 17.80 A ATOM 933 CB ASN A 722 15.469 −5.642 8.241 1.00 17.53 A ATOM 934 CG ASN A 722 15.262 −7.143 8.100 1.00 20.53 A ATOM 935 OD1 ASN A 722 16.227 −7.901 8.085 1.00 22.10 A ATOM 936 ND2 ASN A 722 13.997 −7.582 8.015 1.00 17.67 A ATOM 937 C ASN A 722 16.347 −3.820 9.719 1.00 17.61 A ATOM 938 O ASN A 722 16.752 −3.268 8.697 1.00 18.91 A ATOM 939 N ASP A 723 16.361 −3.247 10.919 1.00 17.15 A ATOM 940 CA ASP A 723 16.817 −1.887 11.101 1.00 19.13 A ATOM 941 CB ASP A 723 16.702 −1.498 12.582 1.00 23.22 A ATOM 942 CG ASP A 723 17.064 −0.043 12.844 1.00 26.94 A ATOM 943 OD1 ASP A 723 16.687 0.837 12.049 1.00 28.14 A ATOM 944 OD2 ASP A 723 17.728 0.220 13.869 1.00 30.54 A ATOM 945 C ASP A 723 18.244 −1.685 10.569 1.00 19.80 A ATOM 946 O ASP A 723 19.168 −2.433 10.906 1.00 15.82 A ATOM 947 N GLY A 724 18.374 −0.682 9.698 1.00 16.08 A ATOM 948 CA GLY A 724 19.644 −0.327 9.089 1.00 15.30 A ATOM 949 C CLY A 724 20.264 −1.401 8.220 1.00 14.31 A ATOM 950 O GLY A 724 21.430 −1.314 7.855 1.00 13.94 A ATOM 951 N GLN A 725 19.481 −2.402 7.843 1.00 14.27 A ATOM 952 CA GLN A 725 20.030 −3.503 7.064 1.00 14.66 A ATOM 953 CB GLN A 725 19.286 −4.784 7.418 1.00 16.87 A ATOM 954 CG GLN A 725 19.316 −5.104 8.912 1.00 18.98 A ATOM 955 CD GLN A 725 20.744 −5.203 9.445 1.00 20.91 A ATOM 956 OE1 GLN A 725 21.198 −4.338 10.202 1.00 25.17 A ATOM 957 NE2 GLN A 725 21.456 −6.248 9.044 1.00 18.71 A ATOM 958 C GLN A 725 20.092 −3.349 5.557 1.00 14.70 A ATOM 959 O GLN A 725 20.722 −4.162 4.895 1.00 13.92 A ATOM 960 N PHE A 726 19.454 −2.321 5.011 1.00 13.07 A ATOM 961 CA PHE A 726 19.459 −2.151 3.561 1.00 15.29 A ATOM 962 CB PHE A 726 18.016 −1.995 3.085 1.00 14.57 A ATOM 963 CG PHE A 726 17.140 −3.143 3.477 1.00 15.22 A ATOM 964 CD1 PHE A 726 16.094 −2.966 4.375 1.00 14.78 A ATOM 965 CD2 PHE A 726 17.399 −4.419 2.984 1.00 14.88 A ATOM 966 CE1 PHE A 726 15.325 −4.042 4.776 1.00 13.36 A ATOM 967 CE2 PHE A 726 16.630 −5.505 3.386 1.00 17.90 A ATOM 968 CZ PHE A 726 15.594 −5.314 4.285 1.00 14.76 A ATOM 969 C PHE A 726 20.300 −0.997 3.050 1.00 13.71 A ATOM 970 O PHE A 726 20.627 −0.070 3.794 1.00 16.24 A ATOM 971 N TEE A 727 20.669 −1.066 1.776 1.00 17.14 A ATOM 972 CA THE A 727 21.443 0.020 1.184 1.00 17.33 A ATOM 973 CB THR A 727 22.177 −0.429 −0.095 1.00 17.31 A ATOM 974 OG1 THR A 727 21.233 −0.637 −1.148 1.00 16.76 A ATOM 975 CG2 THR A 727 22.934 −1.744 0.153 1.00 17.77 A ATOM 976 C THR A 727 20.438 1.121 0.851 1.00 19.38 A ATOM 977 O THR A 727 19.224 0.881 0.853 1.00 18.71 A ATOM 978 N VAL A 728 20.941 2.326 0.601 1.00 17.57 A ATOM 979 CA VAL A 728 20.090 3.465 0.257 1.00 18.19 A ATOM 980 CB VAL A 728 20.924 4.776 0.134 1.00 19.55 A ATOM 981 CG1 VAL A 728 20.029 5.939 −0.320 1.00 20.05 A ATOM 982 CG2 VAL A 728 21.550 5.118 1.487 1.00 18.70 A ATOM 983 C VAL A 728 19.367 3.184 −1.066 1.00 16.00 A ATOM 984 O VAL A 728 18.181 3.482 −1.216 1.00 15.83 A ATOM 985 N ILE A 729 20.085 2.603 −2.019 1.00 16.06 A ATOM 986 CA ILE A 729 19.490 2.274 −3.306 1.00 16.24 A ATOM 987 CB ILE A 729 20.565 1.765 −4.297 1.00 15.78 A ATOM 988 CG2 ILE A 729 19.949 0.856 −5.350 1.00 14.65 A ATOM 989 CG1 ILE A 729 21.272 2.962 −4.948 1.00 18.50 A ATOM 990 CD1 ILE A 729 20.387 3.784 −5.889 1.00 16.84 A ATOM 991 C ILE A 729 18.375 1.247 −3.137 1.00 17.15 A ATOM 992 O ILE A 729 17.377 1.274 −3.870 1.00 13.45 A ATOM 993 N GLN A 730 18.521 0.342 −2.172 1.00 16.67 A ATOM 994 CA GLN A 730 17.461 −0.649 −1.962 1.00 16.00 A ATOM 995 CB GLN A 730 17.922 −1.763 −1.015 1.00 16.68 A ATOM 996 CG GLN A 730 18.885 −2.733 −1.646 1.00 15.89 A ATOM 997 CD GLN A 730 19.389 −3.777 −0.661 1.00 16.94 A ATOM 998 OE1 GLN A 730 19.843 −3.437 0.441 1.00 15.33 A ATOM 999 NE2 GLN A 730 19.312 −5.049 −1.052 1.00 13.76 A ATOM 1000 C GLN A 730 16.202 0.008 −1.397 1.00 15.38 A ATOM 1001 O GLN A 730 15.084 −0.284 −1.838 1.00 15.30 A ATOM 1002 N LEU A 731 16.385 0.896 −0.424 1.00 14.09 A ATOM 1003 CA LEU A 731 15.256 1.589 0.193 1.00 14.64 A ATOM 1004 CB LEU A 731 15.721 2.437 1.377 1.00 13.73 A ATOM 1005 CG LEU A 731 16.298 1.671 2.577 1.00 15.51 A ATOM 1006 CD1 LEU A 731 16.848 2.669 3.569 1.00 15.48 A ATOM 1007 CD2 LEU A 731 15.227 0.797 3.228 1.00 15.71 A ATOM 1008 C LEU A 731 14.570 2.480 −0.828 1.00 15.58 A ATOM 1009 O LEU A 731 13.341 2.582 −0.851 1.00 13.60 A ATOM 1010 N VAL A 732 15.368 3.137 −1.665 1.00 14.16 A ATOM 1011 CA VAL A 732 14.798 4.003 −2.687 1.00 13.56 A ATOM 1012 CB VAL A 732 15.881 4.746 −3.497 1.00 12.54 A ATOM 1013 CG1 VAL A 732 15.225 5.497 −4.664 1.00 13.40 A ATOM 1014 CG2 VAL A 732 16.596 5.748 −2.598 1.00 12.18 A ATOM 1015 C VAL A 732 13.980 3.137 −3.636 1.00 12.77 A ATOM 1016 O VAL A 732 12.917 3.548 −4.097 1.00 16.70 A ATOM 1017 N GLY A 733 14.479 1.932 −3.896 1.00 12.87 A ATOM 1018 CA GLY A 733 13.796 1.003 −4.776 1.00 11.87 A ATOM 1019 C GLY A 733 12.438 0.597 −4.231 1.00 12.83 A ATOM 1020 O GLY A 733 11.485 0.367 −4.989 1.00 10.23 A ATOM 1021 N MET A 734 12.347 0.499 −2.908 1.00 11.75 A ATOM 1022 CA MET A 734 11.086 0.146 −2.263 1.00 11.65 A ATOM 1023 CB MET A 734 11.298 −0.137 −0.773 1.00 11.18 A ATOM 1024 CG MET A 734 12.101 −1.393 −0.479 1.00 13.32 A ATOM 1025 SD MET A 734 12.561 −1.491 1.265 1.00 17.57 A ATOM 1026 CE MET A 734 13.565 −2.978 1.245 1.00 14.96 A ATOM 1027 C MET A 734 10.096 1.297 −2.419 1.00 12.17 A ATOM 1028 O MET A 734 8.916 1.093 −2.732 1.00 12.13 A ATOM 1029 N LEU A 735 10.590 2.510 −2.211 1.00 10.98 A ATOM 1030 CA LEU A 735 9.751 3.692 −2.312 1.00 12.80 A ATOM 1031 CB LEU A 735 10.509 4.919 −1.789 1.00 13.81 A ATOM 1032 CG LEU A 735 10.854 4.931 −0.283 1.00 14.22 A ATOM 1033 CD1 LEU A 735 11.767 6.115 0.009 1.00 15.97 A ATOM 1034 CD2 LEU A 735 9.592 5.036 0.554 1.00 14.12 A ATOM 1035 C LEU A 735 9.277 3.909 −3.756 1.00 12.46 A ATOM 1036 O LEU A 735 8.162 4.387 −3.991 1.00 12.21 A ATOM 1037 N ARG A 736 10.126 3.535 −4.707 1.00 11.75 A ATOM 1038 CA ARG A 736 9.822 3.640 −6.141 1.00 13.68 A ATOM 1039 CB ARG A 736 11.061 3.264 −6.961 1.00 15.62 A ATOM 1040 CG ARG A 736 10.798 2.724 −8.368 1.00 22.11 A ATOM 1041 CD ARG A 736 10.163 3.773 −9.223 1.00 21.46 A ATOM 1042 NE ARG A 736 10.472 3.653 −10.651 1.00 25.32 A ATOM 1043 CZ ARG A 736 9.737 3.010 −11.560 1.00 26.66 A ATOM 1044 NE1 ARG A 736 8.621 2.386 −11.212 1.00 27.03 A ATOM 1045 NH2 ARG A 736 10.092 3.040 −12.848 1.00 26.16 A ATOM 1046 C ARG A 736 8.674 2.697 −6.484 1.00 14.97 A ATOM 1047 O ARG A 736 7.713 3.078 −7.155 1.00 14.53 A ATOM 1048 N GLY A 737 8.788 1.462 −6.010 1.00 14.21 A ATOM 1049 CA GLY A 737 7.757 0.474 −6.256 1.00 13.57 A ATOM 1050 C GLY A 737 6.422 0.906 −5.684 1.00 12.80 A ATOM 1051 O GLY A 737 5.390 0.716 −6.314 1.00 11.94 A ATOM 1052 N ILE A 738 6.437 1.492 −4.490 1.00 14.09 A ATOM 1053 CA ILE A 738 5.208 1.943 −3.855 1.00 11.56 A ATOM 1054 CB ILE A 738 5.467 2.392 −2.405 1.00 11.50 A ATOM 1055 CG2 ILE A 738 4.195 3.031 −1.825 1.00 9.80 A ATOM 1056 CG1 ILE A 738 5.917 1.175 −1.558 1.00 8.91 A ATOM 1057 CD1 ILE A 738 6.389 1.544 −0.153 1.00 8.26 A ATOM 1058 C ILE A 738 4.584 3.110 −4.640 1.00 13.67 A ATOM 1059 O ILE A 738 3.374 3.141 −4.871 1.00 11.58 A ATOM 1060 N ALA A 739 5.416 4.055 −5.070 1.00 12.15 A ATOM 1061 CA ALA A 739 4.918 5.207 −5.831 1.00 12.85 A ATOM 1062 CB ALA A 739 6.054 6.219 −6.067 1.00 9.40 A ATOM 1063 C ALA A 739 4.354 4.728 −7.170 1.00 10.80 A ATOM 1064 O ALA A 739 3.374 5.277 −7.679 1.00 13.80 A ATOM 1065 N ALA A 740 4.980 3.708 −7.736 1.00 8.81 A ATOM 1066 CA ALA A 740 4.526 3.169 −9.009 1.00 11.12 A ATOM 1067 CB ALA A 740 5.508 2.129 −9.514 1.00 9.71 A ATOM 1068 C ALA A 740 3.151 2.532 −8.830 1.00 12.53 A ATOM 1069 O ALA A 740 2.262 2.721 −9.655 1.00 9.41 A ATOM 1070 N GLY A 741 2.992 1.748 −7.765 1.00 10.66 A ATOM 1071 CA GLY A 741 1.700 1.138 −7.516 1.00 10.59 A ATOM 1072 C GLY A 741 0.642 2.211 −7.310 1.00 10.74 A ATOM 1073 O GLY A 741 −0.460 2.097 −7.838 1.00 11.88 A ATOM 1074 N MET A 742 0.988 3.260 −6.564 1.00 9.32 A ATOM 1075 CA MET A 742 0.057 4.342 −6.276 1.00 10.60 A ATOM 1076 CE MET A 742 0.593 5.246 −5.170 1.00 9.60 A ATOM 1077 CG MET A 742 0.530 4.658 −3.753 1.00 15.00 A ATOM 1078 SD MET A 742 −1.113 4.092 −3.272 1.00 12.37 A ATOM 1079 CE MET A 742 −1.973 5.605 −3.201 1.00 7.46 A ATOM 1080 C MET A 742 −0.274 5.184 −7.506 1.00 11.90 A ATOM 1081 O MET A 742 −1.396 5.681 −7.636 1.00 11.73 A ATOM 1082 N LYS A 743 0.710 5.362 −8.382 1.00 12.27 A ATOM 1083 CA LYS A 743 0.510 6.128 −9.606 1.00 14.85 A ATOM 1084 CB LYS A 743 1.828 6.206 −10.386 1.00 14.51 A ATOM 1085 CG LYS A 743 1.892 7.305 −11.431 1.00 17.54 A ATOM 1086 CD LYS A 743 1.282 6.871 −12.720 1.00 18.67 A ATOM 1087 CE LYS A 743 1.404 7.987 −13.780 1.00 21.38 A ATOM 1088 NZ LYS A 743 0.863 7.526 −15.088 1.00 19.61 A ATOM 1089 C LYS A 743 −0.554 5.375 −10.406 1.00 14.04 A ATOM 1090 O LYS A 743 −1.503 5.971 −10.918 1.00 15.53 A ATOM 1091 N TYR A 744 −0.401 4.055 −10.474 1.00 11.88 A ATOM 1092 CA TYR A 744 −1.341 3.213 −11.194 1.00 11.73 A ATOM 1093 CB TYR A 744 −0.884 1.747 −11.168 1.00 10.89 A ATOM 1094 CG TYR A 744 −1.920 0.774 −11.699 1.00 12.71 A ATOM 1095 CD1 TYR A 744 −2.013 0.478 −13.063 1.00 11.56 A ATOM 1096 CE1 TYR A 744 −2.969 −0.441 −13.543 1.00 12.70 A ATOM 1097 CD2 TYR A 744 −2.807 0.144 −10.832 1.00 11.18 A ATOM 1098 CE2 TYR A 744 −3.756 −0.760 −11.299 1.00 12.54 A ATOM 1099 CZ TYR A 744 −3.830 −1.054 −12.644 1.00 12.73 A ATOM 1100 OH TYR A 744 −4.728 −2.010 −13.051 1.00 13.10 A ATOM 1101 C TYR A 744 −2.761 3.333 −10.600 1.00 13.06 A ATOM 1102 O TYR A 744 −3.725 3.511 −11.339 1.00 12.71 A ATOM 1103 N LEU A 745 −2.892 3.239 −9.273 1.00 11.93 A ATOM 1104 CA LEU A 745 −4.203 3.364 −8.634 1.00 9.55 A ATOM 1105 CE LEU A 745 −4.098 3.129 −7.117 1.00 12.28 A ATOM 1106 CG LEU A 745 −3.548 1.739 −6.716 1.00 10.40 A ATOM 1107 CD1 LEU A 745 −3.313 1.648 −5.206 1.00 11.47 A ATOM 1108 CD2 LEU A 745 −4.550 0.682 −7.149 1.00 13.02 A ATOM 1109 C LEU A 745 −4.808 4.755 −8.898 1.00 12.15 A ATOM 1110 O LEU A 745 −5.991 4.876 −9.231 1.00 11.72 A ATOM 1111 N ALA A 746 −4.000 5.796 −8.732 1.00 13.75 A ATOM 1112 CA ALA A 746 −4.447 7.159 −8.972 1.00 13.62 A ATOM 1113 CB ALA A 746 −3.289 8.153 −8.704 1.00 14.55 A ATOM 1114 C ALA A 746 −4.930 7.270 −10.425 1.00 14.12 A ATOM 1115 O ALA A 746 −5.965 7.877 −10.694 1.00 16.20 A ATOM 1116 N ASP A 747 −4.194 6.668 −11.356 1.00 13.55 A ATOM 1117 CA ASP A 747 −4.583 6.692 −12.773 1.00 14.00 A ATOM 1118 CB ASP A 747 −3.563 5.961 −13.641 1.00 14.56 A ATOM 1119 CG ASP A 747 −2.358 6.820 −14.001 1.00 10.40 A ATOM 1120 OD1 ASP A 747 −2.345 8.018 −13.679 1.00 11.42 A ATOM 1121 OD2 ASP A 747 −1.438 6.263 −14.625 1.00 13.31 A ATOM 1122 C ASP A 747 −5.939 6.023 −12.995 1.00 17.40 A ATOM 1123 O ASP A 747 −6.680 6.391 −13.921 1.00 13.00 A ATOM 1124 N MET A 748 −6.238 5.032 −12.151 1.00 15.80 A ATOM 1125 CA MET A 748 −7.491 4.263 −12.210 1.00 17.56 A ATOM 1126 CB MET A 748 −7.333 2.914 −11.491 1.00 18.98 A ATOM 1127 CG MET A 748 −6.414 1.918 −12.149 1.00 24.30 A ATOM 1128 SD MET A 748 −7.172 1.067 −13.532 1.00 32.75 A ATOM 1129 CE MET A 748 −8.491 0.141 −12.704 1.00 26.32 A ATOM 1130 C MET A 748 −8.593 5.022 −11.493 1.00 16.57 A ATOM 1131 O MET A 748 −9.744 4.557 −11.402 1.00 17.25 A ATOM 1132 N ASN A 749 −8.223 6.175 −10.954 1.00 15.84 A ATOM 1133 CA ASN A 749 −9.148 7.007 −10.198 1.00 17.28 A ATOM 1134 CB ASN A 749 −10.408 7.295 −11.017 1.00 22.09 A ATOM 1135 CG ASN A 749 −11.210 8.431 −10.447 1.00 25.81 A ATOM 1136 CD1 ASN A 749 −10.647 9.371 −9.892 1.00 29.95 A ATOM 1137 ND2 ASN A 749 −12.528 8.363 −10.580 1.00 31.13 A ATOM 1138 C ASN A 749 −9.528 6.329 −8.875 1.00 16.80 A ATOM 1139 O ASN A 749 −10.660 6.444 −6.388 1.00 14.69 A ATOM 1140 N TYR A 750 −8.579 5.608 −8.293 1.00 16.08 A ATOM 1141 CA TYR A 750 −8.827 4.949 −7.007 1.00 13.01 A ATOM 1142 CB TYR A 750 −8.345 3.498 −7.042 1.00 13.41 A ATOM 1143 CG TYR A 750 −8.556 2.791 −5.721 1.00 13.96 A ATOM 1144 CD1 TYR A 750 −9.792 2.249 −5.402 1.00 11.49 A ATOM 1145 CE1 TYR A 750 −10.022 1.633 −4.175 1.00 13.84 A ATOM 1146 CD2 TYR A 750 −7.530 2.704 −4.774 1.00 13.22 A ATOM 1147 CE2 TYR A 750 −7.749 2.088 −3.534 1.00 13.77 A ATOM 1148 CZ TYR A 750 −9.003 1.559 −3.251 1.00 14.92 A ATOM 1149 OH TYR A 750 −9.262 0.963 −2.028 1.00 15.35 A ATOM 1150 C TYR A 750 −8.039 5.699 −5.934 1.00 13.00 A ATOM 1151 O TYR A 750 −6.814 5.785 −6.012 1.00 13.01 A ATOM 1152 N VAL A 751 −8.743 6.256 −4.955 1.00 14.41 A ATOM 1153 CA VAL A 751 −8.111 6.968 −3.843 1.00 15.71 A ATOM 1154 CB VAL A 751 −8.968 8.151 −3.365 1.00 17.55 A ATOM 1155 CG1 VAL A 751 −8.324 8.792 −2.143 1.00 20.77 A ATOM 1156 CG2 VAL A 751 −9.123 9.181 −4.491 1.00 18.56 A ATOM 1157 C VAL A 751 −8.027 5.946 −2.715 1.00 16.81 A ATOM 1158 O VAL A 751 −9.058 5.449 −2.267 1.00 15.55 A ATOM 1159 N HIS A 752 −6.814 5.643 −2.258 1.00 14.86 A ATOM 1160 CA HIS A 752 −6.612 4.645 −1.209 1.00 13.56 A ATOM 1161 CB HIS A 752 −5.123 4.316 −1.085 1.00 11.05 A ATOM 1162 CG HIS A 752 −4.852 3.078 −0.290 1.00 8.71 A ATOM 1163 CD2 HIS A 752 −4.529 1.825 −0.681 1.00 10.79 A ATOM 1164 ND1 HIS A 752 −4.946 3.039 1.084 1.00 10.98 A ATOM 1165 CE1 HIS A 752 −4.688 1.614 1.505 1.00 11.77 A ATOM 1166 NE2 HIS A 752 −4.431 1.060 0.454 1.00 10.75 A ATOM 1167 C HIS A 752 −7.149 5.044 0.161 1.00 14.58 A ATOM 1168 O HIS A 752 −7.821 4.251 0.830 1.00 16.10 A ATOM 1169 N ARG A 753 −6.825 6.269 0.573 1.00 15.29 A ATOM 1170 CA ARG A 753 −7.251 6.827 1.855 1.00 17.04 A ATOM 1171 CB ARG A 753 −8.755 6.598 2.068 1.00 21.60 A ATOM 1172 CG ARG A 753 −9.654 7.287 1.056 1.00 25.77 A ATOM 1173 CD ARG A 753 −11.110 7.212 1.484 1.00 31.38 A ATOM 1174 NE ARG A 753 −11.969 8.087 0.685 1.00 33.80 A ATOM 1175 CZ ARG A 753 −13.158 8.533 1.082 1.00 36.41 A ATOM 1176 NH1 ARG A 753 −13.637 8.187 2.271 1.00 35.80 A ATOM 1177 NH2 ARG A 753 −13.864 9.336 0.295 1.00 37.87 A ATOM 1178 C ARG A 753 −6.503 6.326 3.097 1.00 16.08 A ATOM 1179 O ARG A 753 −6.555 6.972 4.144 1.00 15.20 A ATOM 1180 N ASP A 754 −5.819 5.189 3.008 1.00 14.97 A ATOM 1181 CA ASP A 754 −5.101 4.667 4.180 1.00 16.09 A ATOM 1182 CB ASP A 754 −5.941 3.555 4.826 1.00 18.24 A ATOM 1183 CG ASP A 754 −5.413 3.098 6.188 1.00 23.23 A ATOM 1184 OD1 ASP A 754 −4.927 3.920 6.990 1.00 25.55 A ATOM 1185 OD2 ASP A 754 −5.515 1.881 6.469 1.00 28.99 A ATOM 1186 C ASP A 754 −3.702 4.161 3.796 1.00 14.92 A ATOM 1187 O ASP A 754 −3.280 3.078 4.201 1.00 13.06 A ATOM 1188 N LEU A 755 −2.993 4.955 2.998 1.00 14.02 A ATOM 1189 CA LEU A 755 −1.652 4.594 2.572 1.00 13.51 A ATOM 1190 CB LEU A 755 −1.212 5.454 1.384 1.00 9.06 A ATOM 1191 CD LEU A 755 0.216 5.254 0.884 1.00 10.93 A ATOM 1192 CD1 LEU A 755 0.452 3.797 0.483 1.00 9.97 A ATOM 1193 CD2 LEU A 755 0.458 6.186 −0.312 1.00 8.65 A ATOM 1194 C LEU A 755 −0.705 4.772 3.758 1.00 13.01 A ATOM 1195 O LEU A 755 −0.596 5.859 4.346 1.00 13.78 A ATOM 1196 N ALA A 756 −0.043 3.675 4.110 1.00 12.68 A ATOM 1197 CA ALA A 756 0.876 3.623 5.247 1.00 11.51 A ATOM 1198 CB ALA A 756 0.068 3.568 6.560 1.00 9.75 A ATOM 1199 C ALA A 756 1.732 2.361 5.094 1.00 10.18 A ATOM 1200 O ALA A 756 1.303 1.398 4.465 1.00 7.97 A ATOM 1201 N ALA A 757 2.930 2.346 5.671 1.00 7.85 A ATOM 1202 CA ALA A 757 3.802 1.186 5.514 1.00 8.61 A ATOM 1203 CB ALA A 757 5.153 1.430 6.239 1.00 7.83 A ATOM 1204 C ALA A 757 3.148 −0.117 6.016 1.00 8.24 A ATOM 1205 O ALA A 757 3.423 −1.189 5.490 1.00 10.34 A ATOM 1206 N ARG A 758 2.279 −0.026 7.016 1.00 10.60 A ATOM 1207 CA ARG A 758 1.607 −1.219 7.537 1.00 12.89 A ATOM 1208 CB ARG A 758 0.806 −0.895 8.809 1.00 14.94 A ATOM 1209 CG ARG A 758 −0.235 0.190 8.616 1.00 20.57 A ATOM 1210 CD ARG A 758 −1.226 0.256 9.775 1.00 23.51 A ATOM 1211 NE ARG A 758 −2.251 1.267 9.517 1.00 26.29 A ATOM 1212 CZ ARG A 758 −2.017 2.574 9.514 1.00 26.89 A ATOM 1213 NH1 ARG A 758 −0.794 3.029 9.762 1.00 28.84 A ATOM 1214 NH2 ARG A 758 −2.999 3.425 9.259 1.00 29.97 A ATOM 1215 C ARG A 758 0.667 −1.782 6.479 1.00 13.53 A ATOM 1216 O ARG A 758 0.245 −2.942 6.555 1.00 11.71 A ATOM 1217 N ASN A 759 0.348 −0.960 5.486 1.00 12.82 A ATOM 1218 CA ASN A 759 −0.542 −1.401 4.421 1.00 14.76 A ATOM 1219 CB ASN A 759 −1.659 −0.368 4.217 1.00 13.84 A ATOM 1220 CD ASN A 759 −2.575 −0.315 5.409 1.00 17.87 A ATOM 1221 OD1 ASN A 759 −2.929 −1.366 5.947 1.00 14.41 A ATOM 1222 ND2 ASN A 759 −2.942 0.888 5.853 1.00 16.21 A ATOM 1223 C ASN A 759 0.175 −1.727 3.117 1.00 14.12 A ATOM 1224 O ASN A 759 −0.450 −1.885 2.067 1.00 16.83 A ATOM 1225 N ILE A 760 1.499 −1.823 3.194 1.00 12.17 A ATOM 1226 CA ILE A 760 2.316 −2.195 2.045 1.00 10.80 A ATOM 1227 CB ILE A 760 3.503 −1.198 1.811 1.00 10.66 A ATOM 1228 CG2 ILE A 760 4.335 −1.671 0.629 1.00 7.31 A ATOM 1229 CG1 ILE A 760 2.992 0.233 1.571 1.00 9.62 A ATOM 1230 CD1 ILE A 760 2.035 0.369 0.357 1.00 10.93 A ATOM 1231 C ILE A 760 2.905 −3.587 2.374 1.00 12.66 A ATOM 1232 O ILE A 760 3.390 −3.801 3.496 1.00 14.01 A ATOM 1233 N LEU A 761 2.846 −4.534 1.431 1.00 10.97 A ATOM 1234 CA LEU A 761 3.409 −5.874 1.673 1.00 13.49 A ATOM 1235 CB LEU A 761 2.452 −6.983 1.222 1.00 12.03 A ATOM 1236 CG LEU A 761 1.135 −7.005 1.998 1.00 15.46 A ATOM 1237 CD1 LEU A 761 0.168 −8.010 1.371 1.00 15.87 A ATOM 1238 CD2 LEU A 761 1.418 −7.372 3.443 1.00 20.01 A ATOM 1239 C LEU A 761 4.741 −6.004 0.936 1.00 12.83 A ATOM 1240 O LEU A 761 4.955 −5.356 −0.085 1.00 11.29 A ATOM 1241 N VAL A 762 5.623 −6.853 1.457 1.00 11.95 A ATOM 1242 CA VAL A 762 6.957 −7.030 0.885 1.00 10.52 A ATOM 1243 CB VAL A 762 8.017 −6.525 1.894 1.00 11.59 A ATOM 1244 CG1 VAL A 762 9.400 −6.502 1.267 1.00 10.27 A ATOM 1245 CG2 VAL A 762 7.627 −5.142 2.388 1.00 11.18 A ATOM 1246 C VAL A 762 7.243 −8.488 0.525 1.00 11.69 A ATOM 1247 O VAL A 762 7.014 −9.390 1.341 1.00 11.49 A ATOM 1248 N ASN A 763 7.740 −8.734 −0.688 1.00 10.00 A ATOM 1249 CA ASN A 763 8.028 −10.105 −1.082 1.00 13.20 A ATOM 1250 CB ASN A 763 7.586 −10.369 −2.543 1.00 14.49 A ATOM 1251 CG ASN A 763 8.550 −9.829 −3.587 1.00 15.38 A ATOM 1252 OD1 ASN A 763 9.605 −9.278 −3.274 1.00 17.52 A ATOM 1253 ND2 ASN A 763 8.186 −10.010 −4.855 1.00 17.84 A ATOM 1254 C ASN A 763 9.487 −10.470 −0.842 1.00 14.94 A ATOM 1255 O ASN A 763 10.259 −9.643 −0.358 1.00 15.44 A ATOM 1256 N SER A 764 9.862 −11.711 −1.142 1.00 17.21 A ATOM 1257 CA SER A 764 11.233 −12.153 −0.897 1.00 19.91 A ATOM 1258 CB SER A 764 11.372 −13.649 −1.186 1.00 20.57 A ATOM 1259 OG SER A 764 11.104 −13.926 −2.547 1.00 24.62 A ATOM 1260 C SER A 764 12.274 −11.369 −1.687 1.00 21.35 A ATOM 1261 O SER A 764 13.443 −11.319 −1.305 1.00 22.51 A ATOM 1262 N ASN A 765 11.857 −10.746 −2.780 1.00 19.26 A ATOM 1263 CA ASN A 765 12.790 −9.969 −3.571 1.00 19.42 A ATOM 1264 CB ASN A 765 12.513 −10.164 −5.061 1.00 21.15 A ATOM 1265 CG ASN A 765 12.836 −11.572 −5.524 1.00 24.10 A ATOM 1266 OD1 ASN A 765 13.910 −12.096 −5.210 1.00 27.80 A ATOM 1267 ND2 ASN A 765 11.917 −12.194 −6.271 1.00 26.16 A ATOM 1268 C ASN A 765 12.738 −8.489 −3.198 1.00 19.25 A ATOM 1269 O ASN A 765 13.266 −7.631 −3.915 1.00 19.32 A ATOM 1270 N LEU A 766 12.125 −8.198 −2.053 1.00 15.23 A ATOM 1271 CA LEU A 766 12.004 −6.830 −1.552 1.00 15.03 A ATOM 1272 CB LEU A 766 13.386 −6.151 −1.451 1.00 14.51 A ATOM 1273 CG LEU A 766 14.497 −6.907 −0.699 1.00 16.00 A ATOM 1274 CD1 LEU A 766 15.704 −5.956 −0.565 1.00 17.05 A ATOM 1275 CD2 LEU A 766 14.030 −7.346 0.691 1.00 17.26 A ATOM 1276 C LEU A 766 11.054 −5.951 −2.376 1.00 13.94 A ATOM 1277 O LEU A 766 11.021 −4.735 −2.196 1.00 13.56 A ATOM 1278 N VAL A 767 10.289 −6.562 −3.279 1.00 12.87 A ATOM 1279 CA VAL A 767 9.322 −5.808 −4.070 1.00 11.98 A ATOM 1280 CB VAL A 767 8.714 −6.648 −5.202 1.00 9.61 A ATOM 1281 CG1 VAL A 767 7.574 −5.866 −5.857 1.00 9.58 A ATOM 1282 CG2 VAL A 767 9.783 −6.976 −6.240 1.00 9.18 A ATOM 1283 C VAL A 767 8.190 −5.409 −3.130 1.00 13.34 A ATOM 1284 O VAL A 767 7.635 −6.265 −2.436 1.00 12.17 A ATOM 1285 N CYS A 768 7.860 −4.118 −3.099 1.00 12.87 A ATOM 1286 CA CYS A 768 6.786 −3.594 −2.255 1.00 12.04 A ATOM 1287 CB CYS A 768 7.213 −2.257 −1.649 1.00 12.99 A ATOM 1288 SG CYS A 768 8.599 −2.417 −0.477 1.00 15.84 A ATOM 1289 C CYS A 768 5.475 −3.421 −3.027 1.00 13.36 A ATOM 1290 O CYS A 768 5.454 −2.834 −4.116 1.00 13.26 A ATOM 1291 N LYS A 769 4.376 −3.894 −2.440 1.00 12.25 A ATOM 1292 CA LYS A 769 3.073 −3.814 −3.101 1.00 12.28 A ATOM 1293 CB LYS A 769 2.659 −5.209 −3.562 1.00 9.87 A ATOM 1294 CG LYS A 769 3.672 −5.857 −4.462 1.00 13.00 A ATOM 1295 CD LYS A 769 3.170 −7.163 −5.105 1.00 14.19 A ATOM 1296 CE LYS A 769 4.242 −7.757 −6.022 1.00 16.77 A ATOM 1297 NZ LYS A 769 3.710 −8.749 −6.980 1.00 16.50 A ATOM 1298 C LYS A 769 1.978 −3.202 −2.245 1.00 13.01 A ATOM 1299 O LYS A 769 1.844 −3.531 −1.063 1.00 14.29 A ATOM 1300 N VAL A 770 1.184 −2.309 −2.835 1.00 12.10 A ATOM 1301 CA VAL A 770 0.101 −1.677 −2.089 1.00 11.10 A ATOM 1302 CB VAL A 770 −0.512 −0.499 −2.889 1.00 10.58 A ATOM 1303 CG1 VAL A 770 −1.644 0.112 −2.100 1.00 5.30 A ATOM 1304 CG2 VAL A 770 0.570 0.551 −3.186 1.00 6.99 A ATOM 1305 C VAL A 770 −1.000 −2.696 −1.796 1.00 11.89 A ATOM 1306 O VAL A 770 −1.353 −3.491 −2.662 1.00 12.00 A ATOM 1307 N SER A 771 −1.527 −2.667 −0.576 1.00 11.80 A ATOM 1308 CA SER A 771 −2.590 −3.578 −0.150 1.00 14.70 A ATOM 1309 CB SER A 771 −2.002 −4.666 0.765 1.00 17.32 A ATOM 1310 OG SER A 771 −2.990 −5.600 1.144 1.00 19.91 A ATOM 1311 C SER A 771 −3.655 −2.795 0.630 1.00 14.68 A ATOM 1312 O SER A 771 −3.709 −1.562 0.544 1.00 15.55 A ATOM 1313 N ASP A 772 −4.508 −3.504 1.378 1.00 14.81 A ATOM 1314 CA ASP A 772 −5.530 −2.865 2.212 1.00 16.39 A ATOM 1315 CB ASP A 772 −4.852 −1.845 3.134 1.00 19.62 A ATOM 1316 CG ASP A 772 −5.816 −1.172 4.110 1.00 22.71 A ATOM 1317 OD1 ASP A 772 −5.738 0.078 4.232 1.00 26.71 A ATOM 1318 0D2 ASP A 772 −6.622 −1.863 4.762 1.00 20.60 A ATOM 1319 C ASP A 772 −6.633 −2.184 1.391 1.00 15.48 A ATOM 1320 O ASP A 772 −6.867 −0.983 1.528 1.00 15.52 A ATOM 1321 N PHE A 773 −7.302 −2.962 0.546 1.00 16.06 A ATOM 1322 CA PHE A 773 −8.376 −2.449 −0.293 1.00 17.22 A ATOM 1323 CB PHE A 773 −8.295 −3.087 −1.679 1.00 16.56 A ATOM 1324 CG PHE A 773 −7.062 −2.696 −2.441 1.00 14.03 A ATOM 1325 CD1 PHE A 773 −6.005 −3.593 −2.611 1.00 12.33 A ATOM 1326 CD2 PHE A 773 −6.927 −1.396 −2.927 1.00 12.51 A ATOM 1327 CE1 PHE A 773 −4.824 −3.188 −3.251 1.00 14.35 A ATOM 1328 CE2 PHE A 773 −5.757 −0.989 −3.563 1.00 13.76 A ATOM 1329 CZ PHE A 773 −4.706 −1.885 −3.723 1.00 11.63 A ATOM 1330 C PHE A 773 −9.748 −2.693 0.325 1.00 21.10 A ATOM 1331 O PHE A 773 −10.023 −3.784 0.824 1.00 25.25 A ATOM 1332 N PRO A 797 −4.563 6.529 12.016 1.00 37.73 A ATOM 1333 CD PRO A 797 −5.935 5.995 12.099 1.00 39.20 A ATOM 1334 CA PRO A 797 −4.285 7.010 10.661 1.00 36.62 A ATOM 1335 CB PRO A 797 −5.445 6.428 9.856 1.00 37.71 A ATOM 1336 CG PRO A 797 −6.572 6.522 10.818 1.00 37.28 A ATOM 1337 C PRO A 797 −4.206 8.537 10.558 1.00 34.49 A ATOM 1338 O PRO A 797 −3.764 9.071 9.543 1.00 33.47 A ATOM 1339 N ILE A 798 −4.629 9.236 11.609 1.00 32.85 A ATOM 1340 CA ILE A 798 −4.588 10.695 11.606 1.00 29.61 A ATOM 1341 CB ILE A 798 −4.905 11.269 12.997 1.00 30.95 A ATOM 1342 CG2 ILE A 798 −4.587 12.766 13.042 1.00 29.66 A ATOM 1343 CG1 ILE A 798 −6.373 11.020 13.327 1.00 29.77 A ATOM 1344 CD1 ILE A 798 −6.754 11.463 14.701 1.00 32.23 A ATOM 1345 C ILE A 798 −3.241 11.252 11.157 1.00 28.44 A ATOM 1346 O ILE A 798 −3.192 12.111 10.282 1.00 28.15 A ATOM 1347 N ARG A 799 −2.154 10.768 11.752 1.00 26.63 A ATOM 1348 CA ARG A 799 −0.818 11.247 11.403 1.00 26.62 A ATOM 1349 CB ARG A 799 0.193 10.798 12.466 1.00 28.00 A ATOM 1350 CG ARG A 799 0.416 9.294 12.553 1.00 28.23 A ATOM 1351 CD ARG A 799 1.120 8.966 13.857 1.00 29.46 A ATOM 1352 NE ARG A 799 0.298 9.380 14.993 1.00 30.72 A ATOM 1353 CZ ARG A 799 0.771 9.878 16.129 1.00 30.22 A ATOM 1354 NH1 ARG A 799 2.074 10.036 16.303 1.00 28.37 A ATOM 1355 NE2 ARG A 799 −0.066 10.228 17.093 1.00 31.49 A ATOM 1356 C ARG A 799 −0.350 10.789 10.018 1.00 24.48 A ATOM 1357 O ARG A 799 0.781 11.053 9.622 1.00 24.93 A ATOM 1358 N TRP A 800 −1.226 10.102 9.292 1.00 23.10 A ATOM 1359 CA TRP A 800 −0.924 9.619 7.943 1.00 22.60 A ATOM 1360 CB TRP A 800 −1.212 8.118 7.836 1.00 21.43 A ATOM 1361 CG TRP A 800 −0.067 7.225 8.213 1.00 21.86 A ATOM 1362 CD2 TRP A 800 0.187 6.640 9.499 1.00 24.24 A ATOM 1363 CE2 TRP A 800 1.379 5.894 9.388 1.00 23.31 A ATOM 1364 CE3 TRP A 800 −0.477 6.673 10.734 1.00 24.72 A ATOM 1365 CD1 TRP A 800 0.953 6.822 7.404 1.00 20.84 A ATOM 1366 NE1 TRP A 800 1.824 6.023 8.099 1.00 21.54 A ATOM 1367 CZ2 TRP A 800 1.924 5.186 10.464 1.00 25.57 A ATOM 1368 CZ3 TRP A 800 0.067 5.966 11.807 1.00 26.76 A ATOM 1369 CH2 TRP A 800 1.255 5.234 11.662 1.00 25.91 A ATOM 1370 C TRP A 800 −1.818 10.349 6.950 1.00 22.35 A ATOM 1371 O TRP A 800 −1.623 10.276 5.741 1.00 22.75 A ATOM 1372 N THR A 801 −2.805 11.054 7.480 1.00 22.40 A ATOM 1373 CA THR A 801 −3.781 11.739 6.653 1.00 21.32 A ATOM 1374 CE THR A 801 −5.177 11.517 7.242 1.00 20.93 A ATOM 1375 OG1 THR A 801 −5.356 10.114 7.520 1.00 19.55 A ATOM 1376 CG2 THR A 801 −6.253 11.971 6.264 1.00 19.42 A ATOM 1377 C THR A 801 −3.521 13.224 6.483 1.00 22.83 A ATOM 1378 O THR A 801 −3.073 13.901 7.405 1.00 24.26 A ATOM 1379 N ALA A 802 −3.806 13.719 5.285 1.00 23.67 A ATOM 1380 CA ALA A 802 −3.616 15.125 4.961 1.00 24.60 A ATOM 1381 CB ALA A 802 −3.827 15.349 3.472 1.00 21.86 A ATOM 1382 C ALA A 802 −4.567 16.006 5.755 1.00 25.32 A ATOM 1383 O ALA A 802 −5.664 15.586 6.121 1.00 26.16 A ATOM 1384 N PRO A 803 −4.155 17.250 6.032 1.00 26.55 A ATOM 1385 CD PRO A 803 −2.823 17.825 5.768 1.00 25.55 A ATOM 1386 CA PRO A 803 −4.991 18.183 6.791 1.00 27.54 A ATOM 1387 CE PRO A 803 −4.158 19.462 6.789 1.00 29.43 A ATOM 1388 CG PRO A 803 −2.743 18.934 6.788 1.00 29.14 A ATOM 1389 C PRO A 803 −6.384 18.396 6.188 1.00 28.40 A ATOM 1390 O PRO A 803 −7.387 18.318 6.897 1.00 28.43 A ATOM 1391 N GLU A 804 −6.445 18.658 4.884 1.00 29.91 A ATOM 1392 CA GLU A 804 −7.730 18.897 4.231 1.00 31.54 A ATOM 1393 CB GLU A 804 −7.536 19.320 2.764 1.00 29.69 A ATOM 1394 CG GLU A 804 −7.162 18.217 1.779 1.00 29.36 A ATOM 1395 CD GLU A 804 −5.671 17.936 1.723 1.00 26.95 A ATOM 1396 OE1 GLU A 804 −4.921 18.476 2.563 1.00 26.91 A ATOM 1397 OE2 GLU A 804 −5.254 17.164 0.838 1.00 27.14 A ATOM 1398 C GLU A 804 −8.634 17.671 4.318 1.00 32.75 A ATOM 1399 O GLU A 804 −9.857 17.793 4.406 1.00 32.85 A ATOM 1400 N ALA A 805 −8.022 16.492 4.314 1.00 34.37 A ATOM 1401 CA ALA A 805 −8.768 15.244 4.397 1.00 36.04 A ATOM 1402 CB ALA A 805 −7.859 14.069 4.054 1.00 36.25 A ATOM 1403 C ALA A 805 −9.364 15.050 5.787 1.00 37.08 A ATOM 1404 O ALA A 805 −10.422 14.444 5.942 1.00 37.44 A ATOM 1405 N ILE A 806 −8.687 15.564 6.802 1.00 38.80 A ATOM 1406 CA ILE A 806 −9.180 15.425 8.162 1.00 40.65 A ATOM 1407 CB ILE A 806 −8.035 15.591 9.179 1.00 40.28 A ATOM 1408 CG2 ILE A 806 −8.582 15.572 10.601 1.00 39.56 A ATOM 1409 CG1 ILE A 806 −7.019 14.463 8.988 1.00 39.83 A ATOM 1410 CD1 ILE A 806 −5.798 14.585 9.870 1.00 41.52 A ATOM 1411 C ILE A 806 −10.267 16.449 8.457 1.00 42.79 A ATOM 1412 O ILE A 806 −11.265 16.137 9.108 1.00 42.39 A ATOM 1413 N GLN A 807 −10.080 17.665 7.952 1.00 44.65 A ATOM 1414 CA GLN A 807 −11.032 18.746 8.183 1.00 46.54 A ATOM 1415 CB GLN A 807 −10.345 20.091 7.959 1.00 48.25 A ATOM 1416 CG GLN A 807 −11.184 21.287 8.352 1.00 51.25 A ATOM 1417 CD GLN A 807 −10.330 22.490 8.710 1.00 52.70 A ATOM 1418 OE1 GLN A 807 −9.503 22.940 7.914 1.00 52.66 A ATOM 1419 NE2 GLN A 807 −10.524 23.015 9.917 1.00 53.69 A ATOM 1420 C GLN A 807 −12.306 18.679 7.348 1.00 47.43 A ATOM 1421 O GLN A 807 −13.407 18.637 7.899 1.00 48.05 A ATOM 1422 N TYR A 808 −12.161 18.673 6.025 1.00 48.14 A ATOM 1412 CA TYR A 808 −13.319 18.630 5.134 1.00 47.86 A ATOM 1424 CB TYR A 808 −13.151 19.628 3.981 1.00 49.76 A ATOM 1425 CG TYR A 808 −12.690 21.004 4.407 1.00 51.92 A ATOM 1426 CD1 TYR A 808 −11.335 21.288 4.555 1.00 52.77 A ATOM 1427 CE1 TYR A 808 −10.905 22.540 4.976 1.00 54.43 A ATOM 1428 CD2 TYR A 808 −13.610 22.013 4.689 1.00 53.07 A ATOM 1429 CE2 TYR A 808 −13.191 23.271 5.113 1.00 54.30 A ATOM 1430 CZ TYR A 808 −11.836 23.527 5.256 1.00 54.97 A ATOM 1431 OH TYR A 808 −11.404 24.760 5.693 1.00 55.34 A ATOM 1432 C TYR A 808 −13.556 17.244 4.547 1.00 46.87 A ATOM 1433 O TYR A 808 −14.334 17.092 3.608 1.00 45.84 A ATOM 1434 N ARG A 809 −12.884 16.240 5.103 1.00 45.55 A ATOM 1435 CA ARG A 809 −13.004 14.863 4.632 1.00 44.26 A ATOM 1436 CB ARG A 809 −14.346 14.259 5.060 1.00 45.12 A ATOM 1437 CG ARG A 809 −14.499 14.086 6.563 0.00 45.61 A ATOM 1438 CD ARG A 809 −15.764 13.313 6.903 0.00 46.19 A ATOM 1439 NE ARG A 809 −15.851 13.007 8.328 0.00 46.63 A ATOM 1440 CZ ARG A 809 −16.810 12.268 8.878 0.00 46.86 A ATOM 1441 NH1 ARG A 809 −17.771 11.756 8.122 0.00 47.00 A ATOM 1442 NH2 ARG A 809 −16.806 12.038 10.184 0.00 47.00 A ATOM 1443 C ARG A 809 −12.849 14.761 3.115 1.00 42.45 A ATOM 1444 O ARG A 809 −13.488 13.928 2.469 1.00 42.37 A ATOM 1445 N LYS A 810 −11.992 15.610 2.557 1.00 40.09 A ATOM 1446 CA LYS A 810 −11.737 15.617 1.120 1.00 38.13 A ATOM 1447 CB LYS A 810 −11.373 17.030 0.649 1.00 39.28 A ATOM 1448 CG LYS A 810 −12.443 18.075 0.917 1.00 41.84 A ATOM 1449 CD LYS A 810 −12.071 19.415 0.293 1.00 43.21 A ATOM 1450 CE LYS A 810 −13.210 20.414 0.425 1.00 43.84 A ATOM 1451 NZ LYS A 810 −12.950 21.652 −0.356 1.00 44.49 A ATOM 1452 C LYS A 810 −10.594 14.665 0.770 1.00 35.30 A ATOM 1453 O LYS A 810 −9.429 15.050 0.826 1.00 34.59 A ATOM 1454 N PHE A 811 −10.928 13.427 0.417 1.00 32.42 A ATOM 1455 CA PHE A 811 −9.912 12.445 0.056 1.00 29.29 A ATOM 1456 CB PHE A 811 −10.296 11.053 0.539 1.00 29.39 A ATOM 1457 CG PHE A 811 −10.238 10.888 2.023 1.00 29.16 A ATOM 1458 CD1 PHE A 811 −11.317 11.258 2.822 1.00 30.55 A ATOM 1459 CD2 PHE A 811 −9.110 10.342 2.624 1.00 28.31 A ATOM 1460 CE1 PHE A 811 −11.273 11.078 4.202 1.00 31.51 A ATOM 1461 CE2 PHE A 811 −9.051 10.157 3.998 1.00 29.55 A ATOM 1462 CZ PHE A 811 −10.135 10.526 4.792 1.00 31.35 A ATOM 1463 C PHE A 811 −9.705 12.400 −1.444 1.00 27.52 A ATOM 1464 O PHE A 811 −10.646 12.167 −2.198 1.00 26.39 A ATOM 1465 N THR A 812 −8.462 12.617 −1.862 1.00 23.72 A ATOM 1466 CA THR A 812 −8.089 12.617 −3.271 1.00 23.05 A ATOM 1467 CB THR A 812 −7.970 14.054 −3.790 1.00 23.97 A ATOM 1468 OG1 THR A 812 −6.932 14.727 −3.067 1.00 23.73 A ATOM 1469 CG2 THR A 812 −9.283 14.818 −3.564 1.00 25.01 A ATOM 1470 C THR A 812 −6.721 11.964 −3.424 1.00 21.01 A ATOM 1471 O THR A 812 −6.102 11.577 −2.437 1.00 20.62 A ATOM 1472 N SER A 813 −6.237 11.850 −4.655 1.00 20.38 A ATOM 1473 CA SER A 813 −4.918 11.270 −4.859 1.00 20.11 A ATOM 1474 CB SER A 813 −4.616 11.071 −6.350 1.00 18.76 A ATOM 1475 OG SER A 813 −5.445 10.061 −6.898 1.00 18.07 A ATOM 1476 C SER A 813 −3.872 12.185 −4.241 1.00 20.46 A ATOM 1477 O SER A 813 −2.818 11.719 −3.809 1.00 19.84 A ATOM 1478 N ALA A 814 −4.171 13.482 −4.178 1.00 19.76 A ATOM 1479 CA ALA A 814 −3.239 14.450 −3.600 1.00 20.26 A ATOM 1480 CB ALA A 814 −3.710 15.882 −3.875 1.00 19.22 A ATOM 1481 C ALA A 814 −3.182 14.195 −2.110 1.00 19.65 A ATOM 1482 O ALA A 814 −2.178 14.478 −1.446 1.00 18.61 A ATOM 1483 N SER A 815 −4.289 13.691 −1.579 1.00 19.76 A ATOM 1484 CA SER A 815 −4.355 13.364 −0.164 1.00 19.99 A ATOM 1485 CB SER A 815 −5.803 13.086 0.244 1.00 19.81 A ATOM 1486 OG SER A 815 −5.869 12.896 1.640 1.00 27.92 A ATOM 1487 C SER A 815 −3.490 12.114 0.062 1.00 18.44 A ATOM 1488 O SER A 815 −2.786 12.010 1.065 1.00 19.10 A ATOM 1489 N ASP A 816 −3.544 11.169 −0.875 1.00 17.07 A ATOM 1490 CA ASP A 816 −2.734 9.947 −0.774 1.00 15.75 A ATOM 1491 CB ASP A 816 −3.041 8.953 −1.901 1.00 13.79 A ATOM 1492 CG ASP A 816 −4.343 8.184 −1.691 1.00 12.11 A ATOM 1493 OD1 ASP A 816 −4.823 8.097 −0.543 1.00 14.33 A ATOM 1494 OD2 ASP A 816 −4.864 7.646 −2.685 1.00 13.38 A ATOM 1495 C ASP A 816 −1.259 10.307 −0.887 1.00 16.60 A ATOM 1496 O ASP A 816 −0.399 9.571 −0.392 1.00 14.48 A ATOM 1497 N VAL A 817 −0.961 11.419 −1.557 1.00 13.18 A ATOM 1498 CA VAL A 817 0.422 11.826 −1.721 1.00 13.34 A ATOM 1499 CB VAL A 817 0.566 12.960 −2.788 1.00 11.51 A ATOM 1500 CG1 VAL A 817 1.944 13.589 −2.704 1.00 9.74 A ATOM 1501 CG2 VAL A 817 0.376 12.363 −4.179 1.00 11.50 A ATOM 1502 C VAL A 817 1.005 12.286 −0.395 1.00 12.99 A ATOM 1503 O VAL A 817 2.172 12.046 −0.108 1.00 13.15 A ATOM 1504 N TRP A 818 0.189 12.938 0.421 1.00 14.23 A ATOM 1505 CA TRP A 818 0.654 13.378 1.726 1.00 15.45 A ATOM 1506 CB TRP A 818 −0.447 14.188 2.410 1.00 15.49 A ATOM 1507 CG TRP A 818 −0.133 14.556 3.801 1.00 19.74 A ATOM 1508 CD2 TRP A 818 0.180 15.863 4.295 1.00 20.03 A ATOM 1509 CE2 TRP A 818 0.436 15.733 5.676 1.00 21.03 A ATOM 1510 CE3 TRP A 818 0.269 17.131 3.706 1.00 21.31 A ATOM 1511 CD1 TRP A 818 −0.060 13.715 4.869 1.00 19.62 A ATOM 1512 NE1 TRP A 818 0.283 14.410 5.998 1.00 21.47 A ATOM 1513 CZ2 TRP A 818 0.774 16.823 6.481 1.00 20.05 A ATOM 1514 CZ3 TRP A 818 0.606 18.217 4.506 1.00 19.00 A ATOM 1515 CH2 TRP A 818 0.854 18.055 5.878 1.00 20.15 A ATOM 1516 C TRP A 818 0.996 12.121 2.531 1.00 15.99 A ATOM 1517 O TRP A 818 2.033 12.048 3.210 1.00 15.51 A ATOM 1518 N SER A 819 0.118 11.130 2.428 1.00 14.95 A ATOM 1519 CA SER A 819 0.281 9.855 3.122 1.00 15.25 A ATOM 1520 CB SER A 819 −0.929 8.950 2.852 1.00 14.79 A ATOM 1521 OG SER A 819 −2.112 9.536 3.348 1.00 16.39 A ATOM 1522 C SER A 819 1.550 9.181 2.629 1.00 14.02 A ATOM 1523 O SER A 819 2.325 8.640 3.414 1.00 16.48 A ATOM 1524 N TYR A 820 1.765 9.229 1.320 1.00 13.71 A ATOM 1525 CA TYR A 820 2.956 8.636 0.726 1.00 14.58 A ATOM 1526 CB TYR A 820 2.956 8.842 −0.799 1.00 13.45 A ATOM 1527 CG TYR A 820 4.197 8.297 −1.453 1.00 12.89 A ATOM 1528 CD1 TYR A 820 4.336 6.931 −1.732 1.00 15.07 A ATOM 1529 CE1 TYR A 820 5.541 6.419 −2.219 1.00 12.78 A ATOM 1530 CD2 TYR A 820 5.285 9.128 −1.690 1.00 12.38 A ATOM 1531 CE2 TYR A 820 6.466 8.633 −2.166 1.00 11.32 A ATOM 1532 CZ TYR A 820 6.600 7.288 −2.426 1.00 12.29 A ATOM 1533 OH TYR A 820 7.814 6.840 −2.859 1.00 10.71 A ATOM 1534 C TYR A 820 4.210 9.280 1.338 1.00 13.53 A ATOM 1535 O TYR A 820 5.223 8.616 1.545 1.00 13.71 A ATOM 1536 N GLY A 821 4.137 10.574 1.628 1.00 14.63 A ATOM 1537 CA GLY A 821 5.275 11.245 2.218 1.00 13.52 A ATOM 1538 C GLY A 821 5.563 10.662 3.585 1.00 14.77 A ATOM 1539 O GLY A 821 6.719 10.454 3.959 1.00 13.85 A ATOM 1540 N ILE A 822 4.509 10.408 4.347 1.00 15.25 A ATOM 1541 CA ILE A 822 4.690 9.820 5.666 1.00 17.12 A ATOM 1542 CB ILE A 822 3.344 9.674 6.420 1.00 17.21 A ATOM 1543 CG2 ILE A 822 3.569 9.002 7.768 1.00 17.52 A ATOM 1544 CG1 ILE A 822 2.689 11.050 6.577 1.00 17.04 A ATOM 1545 OD1 ILE A 822 3.528 12.069 7.309 1.00 15.74 A ATOM 1546 C ILE A 822 5.326 8.443 5.495 1.00 15.76 A ATOM 1547 O ILE A 822 6.174 8.059 6.293 1.00 17.81 A ATOM 1548 N VAL A 823 4.920 7.710 4.457 1.00 13.84 A ATOM 1549 CA VAL A 823 5.459 6.375 4.199 1.00 12.67 A ATOM 1550 CB VAL A 823 4.738 5.711 2.989 1.00 12.77 A ATOM 1551 CG1 VAL A 823 5.403 4.386 2.633 1.00 10.23 A ATOM 1552 CG2 VAL A 823 3.271 5.494 3.328 1.00 13.23 A ATOM 1553 C VAL A 823 6.961 6.454 3.918 1.00 14.16 A ATOM 1554 O VAL A 823 7.745 5.594 4.339 1.00 12.18 A ATOM 1555 N MET A 824 7.352 7.488 3.188 1.00 12.40 A ATOM 1556 CA MET A 824 8.755 7.710 2.883 1.00 12.87 A ATOM 1557 CB MET A 824 8.938 8.982 2.070 1.00 13.48 A ATOM 1558 CG MET A 824 8.457 8.904 0.641 1.00 11.06 A ATOM 1559 SD MET A 824 8.815 10.500 −0.170 1.00 15.45 A ATOM 1560 CE MET A 824 10.625 10.460 −0.293 1.00 14.21 A ATOM 1561 C MET A 824 9.506 7.876 4.181 1.00 11.22 A ATOM 1562 O MET A 824 10.632 7.411 4.318 1.00 12.72 A ATOM 1563 N TRP A 825 8.882 8.550 5.135 1.00 13.43 A ATOM 1564 CA TRP A 825 9.532 8.760 6.416 1.00 16.39 A ATOM 1565 CB TRP A 825 8.733 9.758 7.251 1.00 17.69 A ATOM 1566 CG TRP A 825 9.485 10.300 8.429 1.00 21.01 A ATOM 1567 CD2 TRP A 825 9.404 9.836 9.783 1.00 22.74 A ATOM 1568 CE2 TRP A 825 10.267 10.646 10.556 1.00 24.73 A ATOM 1569 CE3 TRP A 825 8.686 8.816 10.417 1.00 24.55 A ATOM 1570 CD1 TRP A 825 10.372 11.338 8.433 1.00 22.10 A ATOM 1571 NE1 TRP A 825 10.842 11.554 9.708 1.00 23.09 A ATOM 1572 CZ2 TRP A 825 10.429 10.469 11.937 1.00 23.91 A ATOM 1573 CZ3 TRP A 825 8.848 8.641 11.791 1.00 24.02 A ATOM 1574 CH2 TRP A 825 9.713 9.464 12.532 1.00 24.58 A ATOM 1575 C TRP A 825 9.651 7.415 7.143 1.00 16.44 A ATOM 1576 O TRP A 825 10.718 7.074 7.648 1.00 15.71 A ATOM 1577 N GLU A 826 8.564 6.645 7.185 1.00 15.79 A ATOM 1578 CA GLU A 826 8.597 5.338 7.854 1.00 15.47 A ATOM 1579 CB GLU A 826 7.266 4.609 7.685 1.00 15.67 A ATOM 1580 CG GLU A 826 6.066 5.409 8.128 1.00 17.54 A ATOM 1581 CD GLU A 826 4.797 4.603 8.027 1.00 17.43 A ATOM 1582 OE1 GLU A 826 4.561 3.760 8.918 1.00 17.18 A ATOM 1583 OE2 GLU A 826 4.047 4.793 7.054 1.00 19.83 A ATOM 1584 C GLU A 826 9.698 4.459 7.297 1.00 15.72 A ATOM 1585 O GLU A 826 10.430 3.809 8.043 1.00 14.73 A ATOM 1586 N VAL A 827 9.807 4.448 5.973 1.00 14.75 A ATOM 1587 CA VAL A 827 10.812 3.652 5.293 1.00 13.80 A ATOM 1588 CB VAL A 827 10.605 3.688 3.776 1.00 13.84 A ATOM 1589 CG1 VAL A 827 11.864 3.166 3.064 1.00 15.75 A ATOM 1590 CG2 VAL A 827 9.395 2.845 3.404 1.00 12.52 A ATOM 1591 C VAL A 827 12.241 4.107 5.598 1.00 15.22 A ATOM 1592 O VAL A 827 13.114 3.282 5.855 1.00 15.68 A ATOM 1593 N MET A 828 12.488 5.411 5.571 1.00 15.64 A ATOM 1594 CA MET A 828 13.840 5.885 5.830 1.00 16.82 A ATOM 1595 CB MET A 828 14.020 7.304 5.282 1.00 16.69 A ATOM 1596 CG MET A 828 13.812 7.400 3.764 1.00 15.12 A ATOM 1597 SD MET A 828 14.617 6.077 2.862 1.00 17.16 A ATOM 1598 CE MET A 828 16.377 6.500 3.177 1.00 16.75 A ATOM 1599 C MET A 828 14.182 5.815 7.319 1.00 17.74 A ATOM 1600 O MET A 828 15.353 5.818 7.697 1.00 17.30 A ATOM 1601 N SER A 829 13.146 5.731 8.146 1.00 16.25 A ATOM 1602 CA SER A 829 13.287 5.639 9.602 1.00 19.49 A ATOM 1603 CS SER A 829 12.129 6.360 10.296 1.00 19.11 A ATOM 1604 OG SER A 829 12.153 7.747 10.028 1.00 26.80 A ATOM 1605 C SER A 829 13.263 4.186 10.069 1.00 17.50 A ATOM 1606 O SER A 829 13.340 3.921 11.264 1.00 19.93 A ATOM 1607 N TYR A 830 13.157 3.265 9.118 1.00 15.75 A ATOM 1608 CA TYR A 830 13.053 1.837 9.382 1.00 15.79 A ATOM 1609 CB TYR A 830 14.364 1.250 9.930 1.00 15.94 A ATOM 1610 CG TYR A 830 15.392 0.987 8.861 1.00 15.43 A ATOM 1611 CD1 TYR A 830 16.370 1.925 8.566 1.00 19.30 A ATOM 1612 CE1 TYR A 830 17.330 1.682 7.577 1.00 17.62 A ATOM 1613 CD2 TYR A 830 15.387 −0.202 8.141 1.00 15.96 A ATOM 1614 CE2 TYR A 830 16.332 −0.454 7.156 1.00 17.55 A ATOM 1615 CZ TYR A 830 17.304 0.494 6.883 1.00 16.47 A ATOM 1616 OH TYR A 830 18.260 0.225 5.930 1.00 15.91 A ATOM 1617 C TYR A 830 11.889 1.459 10.298 1.00 16.77 A ATOM 1618 O TYR A 830 12.051 0.715 11.273 1.00 14.45 A ATOM 1619 N GLY A 831 10.707 1.979 9.979 1.00 14.09 A ATOM 1620 CA GLY A 831 9.521 1.635 10.742 1.00 17.12 A ATOM 1621 C GLY A 831 9.224 2.407 12.003 1.00 19.41 A ATOM 1622 O GLY A 831 8.410 1.977 12.827 1.00 19.28 A ATOM 1623 N GLU A 832 9.883 3.545 12.171 1.00 21.71 A ATOM 1624 CA GLU A 832 9.633 4.365 13.340 1.00 23.50 A ATOM 1625 CB GLU A 832 10.627 5.522 13.384 1.00 25.11 A ATOM 1626 CG GLU A 832 10.396 6.521 14.496 1.00 26.95 A ATOM 1627 CD GLU A 832 10.411 5.869 15.874 1.00 32.36 A ATOM 1628 OE1 GLU A 832 9.344 5.380 16.326 1.00 31.18 A ATOM 1629 OE2 GLU A 832 11.497 5.834 16.500 1.00 32.72 A ATOM 1630 C GLU A 832 8.210 4.897 13.216 1.00 24.54 A ATOM 1631 O GLU A 832 7.668 4.981 12.111 1.00 22.49 A ATOM 1632 N ARG A 833 7.608 5.249 14.347 1.00 24.48 A ATOM 1633 CA ARG A 833 6.252 5.780 14.351 1.00 26.11 A ATOM 1634 CB ARG A 833 5.597 5.564 15.720 1.00 28.74 A ATOM 1635 CG ARG A 833 4.146 6.014 15.794 1.00 31.71 A ATOM 1636 CD ARG A 833 3.443 5.386 16.985 1.00 34.54 A ATOM 1637 NE ARG A 833 2.023 5.716 17.036 1.00 36.70 A ATOM 1638 CZ ARG A 833 1.538 6.853 17.521 1.00 38.93 A ATOM 1639 NH1 ARG A 833 2.360 7.776 17.998 1.00 40.22 A ATOM 1640 NH2 ARG A 833 0.230 7.063 17.538 1.00 39.85 A ATOM 1641 C ARG A 833 6.280 7.266 14.019 1.00 26.85 A ATOM 1642 O ARG A 833 7.007 8.038 14.641 1.00 28.24 A ATOM 1643 N PRO A 834 5.495 7.683 13.018 1.00 25.28 A ATOM 1644 CD PRO A 834 4.678 6.857 12.112 1.00 26.97 A ATOM 1645 CA PRO A 834 5.450 9.090 12.624 1.00 24.70 A ATOM 1646 CB PRO A 834 4.381 9.108 11.534 1.00 25.64 A ATOM 1647 CG PRO A 834 4.533 7.759 10.896 1.00 24.55 A ATOM 1648 C PRO A 834 5.086 9.984 13.802 1.00 25.05 A ATOM 1649 O PRO A 834 4.091 9.742 14.487 1.00 23.06 A ATOM 1650 N TYR A 835 5.902 11.013 14.023 1.00 26.38 A ATOM 1651 CA TYR A 835 5.704 11.977 15.102 1.00 26.19 A ATOM 1652 CD TYR A 835 4.303 12.584 15.002 1.00 26.82 A ATOM 1653 CG TYR A 835 4.015 13.202 13.648 1.00 27.32 A ATOM 1654 CD1 TYR A 835 4.405 14.511 13.358 1.00 26.52 A ATOM 1655 CE1 TYR A 835 4.175 15.069 12.101 1.00 26.25 A ATOM 1656 CD2 TYR A 835 3.387 12.464 12.647 1.00 25.35 A ATOM 1657 CE2 TYR A 835 3.153 13.008 11.386 1.00 25.46 A ATOM 1658 CZ TYR A 835 3.550 14.314 11.116 1.00 26.18 A ATOM 1659 OH TYR A 835 3.325 14.859 9.867 1.00 25.65 A ATOM 1660 C TYR A 835 5.933 11.349 16.477 1.00 27.36 A ATOM 1661 O TYR A 835 5.554 11.912 17.505 1.00 28.19 A ATOM 1662 N TRP A 836 6.554 10.174 16.475 1.00 26.91 A ATOM 1663 CA TRP A 836 6.885 9.454 17.699 1.00 28.58 A ATOM 1664 CB TRP A 836 8.097 10.114 18.356 1.00 27.99 A ATOM 1665 CG TRP A 836 9.233 10.282 17.406 1.00 29.96 A ATOM 1666 CD2 TRP A 836 9.533 11.449 16.631 1.00 29.72 A ATOM 1667 CE2 TRP A 836 10.666 11.149 15.847 1.00 30.62 A ATOM 1668 CE3 TRP A 836 8.953 12.722 16.525 1.00 31.28 A ATOM 1669 CD1 TRP A 836 10.169 9.346 17.069 1.00 29.72 A ATOM 1670 NE1 TRP A 836 11.034 9.859 16.133 1.00 29.17 A ATOM 1671 CZ2 TRP A 836 11.235 12.076 14.965 1.00 30.51 A ATOM 1672 CZ3 TRP A 836 9.520 13.646 15.648 1.00 30.96 A ATOM 1673 CH2 TRP A 836 10.649 13.315 14.882 1.00 31.70 A ATOM 1674 C TRP A 836 5.727 9.370 18.688 1.00 29.62 A ATOM 1675 O TRP A 836 4.627 8.945 18.328 1.00 29.84 A ATOM 1676 N ASP A 837 5.977 9.789 19.927 1.00 31.12 A ATOM 1677 CA ASP A 837 4.972 9.743 20.992 1.00 34.13 A ATOM 1678 CB ASP A 837 5.659 9.720 22.365 1.00 34.74 A ATOM 1679 CG ASP A 837 6.593 8.536 22.533 0.00 35.23 A ATOM 1680 OD1 ASP A 837 6.132 7.384 22.389 0.00 35.57 A ATOM 1681 OD2 ASP A 837 7.790 8.758 22.811 0.00 35.57 A ATOM 1682 C ASP A 837 3.954 10.879 20.969 1.00 35.08 A ATOM 1683 O ASP A 837 3.129 10.998 21.875 1.00 35.37 A ATOM 1684 N MET A 838 4.009 11.722 19.946 1.00 36.64 A ATOM 1685 CA MET A 838 3.056 12.821 19.845 1.00 37.58 A ATOM 1686 CB MET A 838 3.315 13.648 18.594 1.00 37.74 A ATOM 1687 CG MET A 838 4.207 14.831 18.800 1.00 37.49 A ATOM 1688 SD MET A 838 4.120 15.864 17.349 1.00 40.87 A ATOM 1689 CE MET A 838 5.651 15.422 16.541 1.00 37.80 A ATOM 1690 C MET A 838 1.638 12.295 19.771 1.00 38.85 A ATOM 1691 O MET A 838 1.392 11.235 19.196 1.00 38.49 A ATOM 1692 N THR A 839 0.708 13.052 20.345 1.00 40.77 A ATOM 1693 CA THR A 839 −0.707 12.691 20.332 1.00 42.26 A ATOM 1694 CB THR A 839 −1.470 13.372 21.493 1.00 42.77 A ATOM 1695 OG1 THR A 839 −1.599 14.773 21.224 0.00 42.95 A ATOM 1696 CG2 THR A 839 −0.719 13.188 22.806 0.00 42.95 A ATOM 1697 C THR A 839 −1.289 13.184 19.007 1.00 42.46 A ATOM 1698 O THR A 839 −0.688 14.030 18.348 1.00 42.49 A ATOM 1699 N ASN A 840 −2.450 12.660 18.616 1.00 43.26 A ATOM 1700 CA ASN A 840 −3.078 13.075 17.363 1.00 44.27 A ATOM 1701 CB ASN A 840 −4.419 12.360 17.154 1.00 43.58 A ATOM 1702 CG ASN A 840 −4.256 10.885 16.855 1.00 43.42 A ATOM 1703 OD1 ASN A 840 −3.230 10.460 16.328 1.00 42.91 A ATOM 1704 ND2 ASN A 840 −5.278 10.097 17.172 1.00 44.00 A ATOM 1705 C ASN A 840 −3.299 14.585 17.327 1.00 44.84 A ATOM 1706 O ASN A 840 −3.017 15.236 16.321 1.00 45.54 A ATOM 1707 N GLN A 841 −3.798 15.141 18.427 1.00 45.95 A ATOM 1708 CA GLN A 841 −4.046 16.573 18.497 1.00 46.24 A ATOM 1709 CB GLN A 841 −4.718 16.947 19.818 1.00 47.54 A ATOM 1710 CG GLN A 841 −5.283 18.356 19.818 1.00 48.27 A ATOM 1711 CD GLN A 841 −6.207 18.594 18.638 1.00 49.43 A ATOM 1712 OE1 GLN A 841 −7.199 17.884 18.460 1.00 49.85 A ATOM 1713 NE2 GLN A 841 −5.882 19.591 17.820 1.00 49.98 A ATOM 1714 C GLN A 841 −2.744 17.347 18.350 1.00 46.35 A ATOM 1715 O GLN A 841 −2.702 18.373 17.673 1.00 46.78 A ATOM 1716 N ASP A 842 −1.682 16.861 18.984 1.00 45.35 A ATOM 1717 CA ASP A 842 −0.396 17.531 18.878 1.00 45.11 A ATOM 1718 CB ASP A 842 0.651 16.836 19.745 1.00 47.46 A ATOM 1719 CG ASP A 842 0.324 16.913 21.224 1.00 49.71 A ATOM 1720 OD1 ASP A 842 −0.182 17.971 21.667 1.00 50.47 A ATOM 1721 OD2 ASP A 842 0.583 15.923 21.942 1.00 50.96 A ATOM 1722 C ASP A 842 0.059 17.535 17.424 1.00 43.89 A ATOM 1723 O ASP A 842 0.540 18.549 16.923 1.00 43.19 A ATOM 1724 N VAL A 843 −0.099 16.397 16.752 1.00 42.58 A ATOM 1725 CA VAL A 843 0.285 16.281 15.351 1.00 41.17 A ATOM 1726 CB VAL A 843 −0.012 14.869 14.795 1.00 41.26 A ATOM 1727 CG1 VAL A 843 0.278 14.828 13.308 1.00 39.84 A ATOM 1728 CG2 VAL A 843 0.831 13.829 15.530 1.00 41.01 A ATOM 1729 C VAL A 843 −0.481 17.301 14.518 1.00 40.78 A ATOM 1730 O VAL A 843 0.103 18.029 13.714 1.00 38.98 A ATOM 1731 N ILE A 844 −1.795 17.340 14.717 1.00 40.52 A ATOM 1732 CA ILE A 844 −2.657 18.269 14.003 1.00 41.21 A ATOM 1733 CB ILE A 844 −4.123 18.129 14.470 1.00 40.73 A ATOM 1734 CG2 ILE A 844 −4.995 19.190 13.800 1.00 40.70 A ATOM 1735 CG1 ILE A 844 −4.625 16.716 14.160 1.00 40.24 A ATOM 1736 CD1 ILE A 844 −6.004 16.413 14.694 1.00 39.42 A ATOM 1737 C ILE A 844 −2.196 19.706 14.237 1.00 42.20 A ATOM 1738 O ILE A 844 −2.035 20.478 13.289 1.00 42.32 A ATOM 1739 N ASN A 845 −1.988 20.059 15.502 1.00 42.47 A ATOM 1740 CA ASN A 845 −1.550 21.405 15.845 1.00 43.99 A ATOM 1741 CB ASN A 845 −1.525 21.606 17.361 1.00 45.43 A ATOM 1742 CG ASN A 845 −2.885 21.417 17.998 1.00 46.85 A ATOM 1743 OD1 ASN A 845 −3.903 21.851 17.458 1.00 47.77 A ATOM 1744 ND2 ASN A 845 −2.908 20.779 19.163 1.00 48.25 A ATOM 1745 C ASN A 845 −0.162 21.664 15.286 1.00 43.59 A ATOM 1746 O ASN A 845 0.123 22.750 14.784 1.00 43.60 A ATOM 1747 N ALA A 846 0.702 20.660 15.376 1.00 42.78 A ATOM 1748 CA ALA A 846 2.057 20.793 14.870 1.00 42.00 A ATOM 1749 CB ALA A 846 2.829 19.497 15.092 1.00 41.98 A ATOM 1750 C ALA A 846 2.021 21.142 13.386 1.00 41.78 A ATOM 1751 O ALA A 846 2.662 22.100 12.954 1.00 41.69 A ATOM 1752 N ILE A 847 1.269 20.364 12.609 1.00 41.74 A ATOM 1753 CA ILE A 847 1.155 20.600 11.173 1.00 41.99 A ATOM 1754 CB ILE A 847 0.250 19.540 10.492 1.00 41.47 A ATOM 1755 CG2 ILE A 847 0.083 19.863 9.013 1.00 41.65 A ATOM 1756 CG1 ILE A 847 0.869 18.148 10.641 1.00 41.58 A ATOM 1757 CD1 ILE A 847 2.243 18.014 10.006 1.00 41.53 A ATOM 1758 C ILE A 847 0.584 21.990 10.906 1.00 42.01 A ATOM 1759 O ILE A 847 1.032 22.685 9.996 1.00 41.61 A ATOM 1760 N GLU A 848 −0.402 22.388 11.704 1.00 42.81 A ATOM 1761 CA GLU A 848 −1.022 23.700 11.563 1.00 43.79 A ATOM 1762 CB GLU A 848 −2.158 23.866 12.576 1.00 43.97 A ATOM 1763 CG GLU A 848 −3.380 23.013 12.281 0.00 44.75 A ATOM 1764 CD GLU A 848 −4.518 23.276 13.247 0.00 45.09 A ATOM 1765 OE1 GLU A 848 −4.985 24.432 13.317 0.00 45.34 A ATOM 1766 OE2 GLU A 848 −4.947 22.326 13.935 0.00 45.34 A ATOM 1767 C GLU A 848 0.011 24.806 11.760 1.00 44.25 A ATOM 1768 O GLU A 848 −0.033 25.830 11.082 1.00 44.97 A ATOM 1769 N GLN A 849 0.939 24.588 12.689 1.00 43.53 A ATOM 1770 CA GLN A 849 1.997 25.552 12.974 1.00 43.30 A ATOM 1771 CE GLN A 849 2.554 25.328 14.380 1.00 43.26 A ATOM 1772 CG GLN A 849 1.549 25.528 15.492 0.00 44.28 A ATOM 1773 CD GLN A 849 1.042 26.951 15.557 0.00 44.64 A ATOM 1774 OE1 GLN A 849 1.816 27.889 15.745 0.00 44.94 A ATOM 1775 NE2 GLN A 849 −0.264 27.121 15.399 0.00 44.94 A ATOM 1776 C GLN A 849 3.126 25.402 11.959 1.00 43.40 A ATOM 1777 O GLN A 849 4.252 25.842 12.199 1.00 43.15 A ATOM 1778 N ASP A 850 2.814 24.770 10.830 1.00 43.13 A ATOM 1779 CA ASP A 850 3.780 24.545 9.760 1.00 42.79 A ATOM 1780 CE ASP A 850 4.287 25.888 9.222 1.00 43.87 A ATOM 1781 CG ASP A 850 3.260 26.586 8.350 1.00 45.00 A ATOM 1782 OD1 ASP A 850 2.980 26.080 7.245 1.00 47.53 A ATOM 1783 OD2 ASP A 850 2.724 27.634 8.767 1.00 45.98 A ATOM 1784 C ASP A 850 4.957 23.652 10.162 1.00 41.93 A ATOM 1785 O ASP A 850 6.064 23.796 9.651 1.00 42.38 A ATOM 1786 N TYR A 851 4.709 22.718 11.073 1.00 40.80 A ATOM 1787 CA TYR A 851 5.752 21.795 11.512 1.00 39.73 A ATOM 1788 CE TYR A 851 5.481 21.311 12.930 1.00 39.91 A ATOM 1789 CG TYR A 851 6.348 20.139 13.323 1.00 39.84 A ATOM 1790 CD1 TYR A 851 7.674 20.327 13.710 1.00 40.12 A ATOM 1791 CE1 TYR A 851 8.478 19.249 14.062 1.00 39.79 A ATOM 1792 CD2 TYR A 851 5.847 18.837 13.294 1.00 40.19 A ATOM 1793 CE2 TYR A 851 6.643 17.751 13.642 1.00 39.38 A ATOM 1794 CZ TYR A 851 7.955 17.964 14.027 1.00 39.62 A ATOM 1795 OH TYR A 851 8.742 16.899 14.388 1.00 36.75 A ATOM 1796 C TYR A 851 5.811 20.577 10.592 1.00 37.96 A ATOM 1797 O TYR A 851 4.778 20.053 10.185 1.00 39.15 A ATOM 1798 N ARG A 852 7.018 20.127 10.273 1.00 35.12 A ATOM 1799 CA ARG A 852 7.185 18.961 9.419 1.00 33.58 A ATOM 1800 CE ARG A 852 7.568 19.394 8.003 1.00 32.00 A ATOM 1801 CG ARG A 852 6.478 20.173 7.287 1.00 31.55 A ATOM 1802 CD ARG A 852 5.271 19.293 7.006 1.00 29.23 A ATOM 1803 NE ARC A 852 4.254 19.976 6.206 1.00 30.58 A ATOM 1804 CZ ARG A 852 3.358 20.835 6.688 1.00 28.76 A ATOM 1805 NE1 ARG A 852 3.336 21.132 7.980 1.00 27.10 A ATOM 1806 NH2 ARC A 852 2.476 21.393 5.876 1.00 28.74 A ATOM 1807 C ARG A 852 8.253 18.033 9.992 1.00 32.81 A ATOM 1808 O ARG A 852 9.260 18.490 10.524 1.00 33.32 A ATOM 1809 N LEU A 853 8.025 16.729 9.881 1.00 31.16 A ATOM 1810 CA LEU A 853 8.963 15.741 10.392 1.00 29.31 A ATOM 1811 CB LEU A 853 8.493 14.330 10.040 1.00 28.71 A ATOM 1812 CG LEU A 853 7.220 13.837 10.730 1.00 31.23 A ATOM 1813 CD1 LEU A 853 6.775 12.514 10.090 1.00 29.70 A ATOM 1814 CD2 LEU A 853 7.472 13.662 12.227 1.00 31.09 A ATOM 1815 C LEU A 853 10.360 15.959 9.832 1.00 29.46 A ATOM 1816 O LEU A 853 10.534 16.191 8.633 1.00 27.80 A ATOM 1817 N PRO A 854 11.379 15.878 10.700 1.00 29.14 A ATOM 1818 CD PRO A 854 11.277 15.586 12.144 1.00 29.31 A ATOM 1819 CA PRO A 854 12.775 16.063 10.302 1.00 29.67 A ATOM 1820 CB PRO A 854 13.487 16.207 11.641 1.00 29.68 A ATOM 1821 CG PRO A 854 12.715 15.259 12.514 1.00 29.75 A ATOM 1822 C PRO A 854 13.278 14.861 9.511 1.00 29.68 A ATOM 1823 O PRO A 854 12.659 13.803 9.520 1.00 29.00 A ATOM 1824 N PRO A 855 14.415 15.008 8.820 1.00 30.63 A ATOM 1825 CD PRO A 855 15.242 16.220 8.668 1.00 30.11 A ATOM 1826 CA PRO A 855 14.965 13.897 8.040 1.00 30.85 A ATOM 1827 CB PRO A 855 16.089 14.561 7.246 1.00 31.70 A ATOM 1828 CG PRO A 855 16.548 15.653 8.163 1.00 29.94 A ATOM 1829 C PRO A 855 15.479 12.757 8.919 1.00 32.90 A ATOM 1830 O PRO A 855 16.201 12.990 9.886 1.00 33.00 A ATOM 1831 N PRO A 856 15.092 11.508 8.602 1.00 33.31 A ATOM 1832 CD PRO A 856 14.065 11.113 7.620 1.00 32.70 A ATOM 1833 CA PRO A 856 15.542 10.348 9.380 1.00 34.07 A ATOM 1834 CM PRO A 856 14.894 9.172 8.649 1.00 33.02 A ATOM 1835 CG PRO A 856 13.617 9.767 8.158 1.00 33.24 A ATOM 1836 C PRO A 856 17.073 10.258 9.374 1.00 34.59 A ATOM 1837 O PRO A 856 17.732 10.793 8.484 1.00 34.67 A ATOM 1838 N MET A 857 17.633 9.571 10.363 1.00 35.13 A ATOM 1839 CA MET A 857 19.081 9.429 10.467 1.00 34.34 A ATOM 1840 CM MET A 857 19.432 8.523 11.650 1.00 34.60 A ATOM 1841 CG MET A 857 20.891 8.620 12.117 1.00 36.07 A ATOM 1842 SD MET A 857 21.222 7.511 13.500 0.00 36.17 A ATOM 1843 CE MET A 857 20.786 8.554 14.888 0.00 36.58 A ATOM 1844 C MET A 857 19.673 8.865 9.178 1.00 33.94 A ATOM 1845 O MET A 857 19.195 7.858 8.643 1.00 32.79 A ATOM 1846 N ASP A 858 20.713 9.533 8.685 1.00 32.95 A ATOM 1847 CA ASP A 858 21.398 9.120 7.463 1.00 32.12 A ATOM 1848 CB ASP A 858 21.957 7.697 7.631 1.00 33.12 A ATOM 1849 CG ASP A 858 22.948 7.591 8.778 0.00 33.41 A ATOM 1850 OD1 ASP A 858 23.981 8.292 8.740 0.00 33.74 A ATOM 1851 OD2 ASP A 858 22.694 6.809 9.719 0.00 33.74 A ATOM 1852 C ASP A 858 20.500 9.181 6.227 1.00 30.87 A ATOM 1853 O ASP A 858 20.787 8.546 5.212 1.00 31.21 A ATOM 1854 N CYS A 859 19.420 9.951 6.299 1.00 29.14 A ATOM 1855 CA CYS A 859 18.514 10.056 5.158 1.00 28.23 A ATOM 1856 CM CYS A 859 17.091 10.370 5.620 1.00 27.03 A ATOM 1857 SG CYS A 859 15.950 10.675 4.219 1.00 25.20 A ATOM 1858 C CYS A 859 18.951 11.128 4.172 1.00 26.49 A ATOM 1859 O CYS A 859 19.063 12.297 4.535 1.00 27.20 A ATOM 1860 N PRO A 860 19.187 10.747 2.905 1.00 25.74 A ATOM 1861 CD PRO A 860 19.019 9.402 2.329 1.00 25.44 A ATOM 1862 CA PRO A 860 19.610 11.703 1.877 1.00 25.49 A ATOM 1863 CB PRO A 860 19.450 10.911 0.584 1.00 26.82 A ATOM 1864 CG PRO A 860 19.754 9.518 1.013 1.00 25.74 A ATOM 1865 C PRO A 860 18.750 12.965 1.875 1.00 25.80 A ATOM 1866 O PRO A 860 17.528 12.887 2.037 1.00 23.12 A ATOM 1867 N SER A 861 19.383 14.123 1.685 1.00 24.04 A ATOM 1868 CA SER A 861 18.651 15.390 1.661 1.00 24.93 A ATOM 1869 CB SER A 861 19.597 16.579 1.437 1.00 24.17 A ATOM 1870 OG SER A 861 20.464 16.754 2.533 1.00 28.72 A ATOM 1871 C SER A 861 17.596 15.405 0.558 1.00 22.46 A ATOM 1872 O SER A 861 16.491 15.887 0.765 1.00 23.97 A ATOM 1873 N ALA A 862 17.937 14.886 −0.612 1.00 22.99 A ATOM 1874 CA ALA A 862 16.990 14.879 −1.715 1.00 23.51 A ATOM 1875 CB ALA A 862 17.626 14.254 −2.962 1.00 25.30 A ATOM 1876 C ALA A 862 15.720 14.121 −1.327 1.00 23.45 A ATOM 1877 O ALA A 862 14.619 14.549 −1.667 1.00 22.65 A ATOM 1878 N LEU A 863 15.870 13.004 −0.615 1.00 21.36 A ATOM 1879 CA LEU A 863 14.703 12.232 −0.186 1.00 20.64 A ATOM 1880 CB LEU A 863 15.110 10.907 0.470 1.00 17.21 A ATOM 1881 CG LEU A 863 15.473 9.807 −0.522 1.00 17.62 A ATOM 1882 CD1 LEU A 863 15.995 8.573 0.220 1.00 19.11 A ATOM 1883 CD2 LEU A 863 14.236 9.465 −1.353 1.00 16.32 A ATOM 1884 C LEU A 863 13.821 13.010 0.774 1.00 19.07 A ATOM 1885 O LEU A 863 12.595 13.005 0.641 1.00 20.62 A ATOM 1886 N HIS A 864 14.434 13.683 1.741 1.00 19.85 A ATOM 1887 CA HIS A 864 13.643 14.448 2.686 1.00 18.66 A ATOM 1888 CB HIS A 864 14.496 14.954 3.847 1.00 19.81 A ATOM 1889 CG HIS A 864 13.700 15.626 4.922 1.00 19.98 A ATOM 1890 CD2 HIS A 864 12.826 15.127 5.828 1.00 20.76 A ATOM 1891 ND1 HIS A 864 13.735 16.988 5.133 1.00 21.33 A ATOM 1892 CE1 HIS A 864 12.919 17.299 6.125 1.00 22.47 A ATOM 1893 NE2 HIS A 864 12.355 16.187 6.564 1.00 22.76 A ATOM 1894 C HIS A 864 12.968 15.619 1.983 1.00 19.62 A ATOM 1895 O HIS A 864 11.897 16.052 2.366 1.00 19.61 A ATOM 1896 N GLN A 865 13.641 16.143 0.952 1.00 19.53 A ATOM 1897 CA GLN A 865 13.039 17.259 0.238 1.00 19.79 A ATOM 1898 CB GLN A 865 13.977 17.808 −0.837 1.00 19.80 A ATOM 1899 CG GLN A 865 13.379 18.989 −1.567 1.00 21.23 A ATOM 1900 CD GLN A 865 13.013 20.114 −0.618 1.00 22.98 A ATOM 1901 OE1 GLN A 865 13.868 20.627 0.105 1.00 26.38 A ATOM 1902 NE2 GLN A 865 11.739 20.504 −0.613 1.00 21.44 A ATOM 1903 C GLN A 865 11.766 16.750 −0.416 1.00 19.00 A ATOM 1904 O GLN A 865 10.735 17.419 −0.396 1.00 19.67 A ATOM 1905 N LEU A 866 11.841 15.559 −0.997 1.00 19.26 A ATOM 1906 CA LEU A 866 10.663 14.988 −1.632 1.00 18.45 A ATOM 1907 CB LEU A 866 11.014 13.649 −2.283 1.00 18.07 A ATOM 1908 CG LEU A 866 9.887 12.930 −3.021 1.00 19.78 A ATOM 1909 CD1 LEU A 866 9.168 13.903 −3.967 1.00 18.91 A ATOM 1910 CD2 LEU A 866 10.467 11.754 −3.775 1.00 20.97 A ATOM 1911 C LEU A 866 9.546 14.824 −0.589 1.00 18.47 A ATOM 1912 O LEU A 866 8.367 15.026 −0.890 1.00 17.51 A ATOM 1913 N MET A 867 9.921 14.476 0.641 1.00 18.09 A ATOM 1914 CA MET A 867 8.946 14.318 1.711 1.00 18.01 A ATOM 1915 CB MET A 867 9.632 13.865 3.005 1.00 19.66 A ATOM 1916 CG MET A 867 10.077 12.419 2.991 1.00 20.12 A ATOM 1917 SD MET A 867 10.968 11.976 4.495 1.00 22.40 A ATOM 1918 CE MET A 867 12.235 10.954 3.814 1.00 22.54 A ATOM 1919 C MET A 867 8.228 15.640 1.965 1.00 18.98 A ATOM 1920 O MET A 867 6.996 15.686 2.058 1.00 17.83 A ATOM 1921 N LEU A 868 9.007 16.712 2.089 1.00 18.92 A ATOM 1922 CA LEU A 868 8.447 18.042 2.326 1.00 20.03 A ATOM 1923 CB LEU A 868 9.566 19.083 2.455 1.00 21.62 A ATOM 1924 CG LEU A 868 10.538 18.913 3.628 1.00 22.08 A ATOM 1925 CD1 LEU A 868 11.607 20.012 3.578 1.00 21.68 A ATOM 1926 CD2 LEU A 868 9.772 18.989 4.942 1.00 18.97 A ATOM 1927 C LEU A 868 7.506 18.444 1.191 1.00 19.33 A ATOM 1928 O LEU A 868 6.501 19.111 1.420 1.00 20.63 A ATOM 1929 N ASP A 869 7.836 18.037 −0.031 1.00 17.79 A ATOM 1930 CA ASP A 869 7.001 18.360 −1.183 1.00 18.56 A ATOM 1931 CB ASP A 869 7.707 17.971 −2.484 1.00 17.65 A ATOM 1932 CG ASP A 869 8.988 18.762 −2.703 1.00 18.80 A ATOM 1933 OD1 ASP A 869 9.175 19.790 −2.021 1.00 16.81 A ATOM 1934 OD2 ASP A 869 9.799 18.364 −3.557 1.00 18.79 A ATOM 1935 C ASP A 869 5.664 17.651 −1.072 1.00 20.40 A ATOM 1936 O ASP A 869 4.631 18.197 −1.460 1.00 21.71 A ATOM 1937 N CYS A 870 5.682 16.439 −0.524 1.00 18.78 A ATOM 1938 CA CYS A 870 4.456 15.670 −0.354 1.00 19.36 A ATOM 1939 CB CYS A 870 4.769 14.201 −0.039 1.00 15.21 A ATOM 1940 SO CYS A 870 5.477 13.278 −1.422 1.00 17.93 A ATOM 1941 C CYS A 870 3.616 16.256 0.769 1.00 16.15 A ATOM 1942 O CYS A 870 2.390 16.090 0.785 1.00 20.18 A ATOM 1943 N TRP A 871 4.259 16.956 1.702 1.00 19.04 A ATOM 1944 CA TRP A 871 3.529 17.534 2.833 1.00 20.40 A ATOM 1945 CB TRP A 871 4.306 17.335 4.151 1.00 20.01 A ATOM 1946 CG TRP A 871 4.663 15.890 4.480 1.00 21.12 A ATOM 1947 CD2 TRP A 871 5.874 15.424 5.095 1.00 19.64 A ATOM 1948 CE2 TRP A 871 5.778 14.014 5.204 1.00 18.64 A ATOM 1949 CE3 TRP A 871 7.029 16.060 5.563 1.00 18.54 A ATOM 1950 CD1 TRP A 871 3.897 14.770 4.254 1.00 21.26 A ATOM 1951 NE1 TRP A 871 4.567 13.642 4.685 1.00 19.40 A ATOM 1952 CZ2 TRP A 871 6.797 13.232 5.762 1.00 18.78 A ATOM 1953 CZ3 TRP A 871 8.045 15.282 6.120 1.00 19.69 A ATOM 1954 CH2 TRP A 871 7.920 13.878 6.214 1.00 19.97 A ATOM 1955 C TRP A 871 3.168 19.012 2.669 1.00 20.88 A ATOM 1956 O TRP A 871 2.999 19.736 3.654 1.00 21.06 A ATOM 1957 N GLN A 872 3.055 19.459 1.424 1.00 22.74 A ATOM 1958 CA GLN A 872 2.680 20.846 1.157 1.00 25.25 A ATOM 1959 CB GLN A 872 2.768 21.158 −0.337 1.00 23.93 A ATOM 1960 CG GLN A 872 4.174 21.383 −0.816 1.00 29.27 A ATOM 1961 CD GLN A 872 4.857 22.495 −0.047 1.00 32.45 A ATOM 1962 OE1 GLN A 872 4.377 23.628 −0.015 1.00 34.77 A ATOM 1963 NE2 GLN A 872 5.979 22.178 0.579 1.00 35.29 A ATOM 1964 C GLN A 872 1.260 21.073 1.639 1.00 25.69 A ATOM 1965 O GLN A 872 0.351 20.310 1.301 1.00 26.55 A ATOM 1966 N LYS A 873 1.081 22.112 2.445 1.00 26.47 A ATOM 1967 CA LYS A 873 0.224 22.463 2.990 1.00 27.95 A ATOM 1968 CB LYS A 873 0.139 23.849 3.639 1.00 28.61 A ATOM 1969 CG LYS A 873 1.390 24.304 4.360 1.00 29.84 A ATOM 1970 CD LYS A 873 1.188 25.685 4.968 0.00 30.40 A ATOM 1971 CE LYS A 873 2.412 26.130 5.752 0.00 30.90 A ATOM 1972 NZ LYS A 873 2.223 27.477 6.360 0.00 31.23 A ATOM 1973 C LYS A 873 1.281 22.446 1.886 1.00 29.41 A ATOM 1974 O LYS A 873 2.320 21.800 2.022 1.00 28.03 A ATOM 1975 N ASP A 874 1.008 23.156 0.793 1.00 30.47 A ATOM 1976 CA ASP A 874 1.930 23.211 −0.340 1.00 32.13 A ATOM 1977 CB ASP A 874 1.585 24.399 −1.247 1.00 34.07 A ATOM 1978 CD ASP A 874 2.640 24.656 −2.304 1.00 36.22 A ATOM 1979 OD1 ASP A 874 3.160 23.678 −2.887 1.00 36.33 A ATOM 1980 OD2 ASP A 874 2.944 25.844 −2.560 1.00 38.96 A ATOM 1981 C ASP A 874 1.806 21.919 −1.146 1.00 30.91 A ATOM 1982 O ASP A 874 0.758 21.653 −1.727 1.00 30.73 A ATOM 1983 N ARG A 875 2.876 21.134 −1.207 1.00 30.76 A ATOM 1984 CA ARG A 875 2.837 19.870 −1.939 1.00 30.91 A ATOM 1985 CB ARG A 875 4.177 19.138 −1.832 1.00 32.82 A ATOM 1986 CG ARG A 875 5.316 19.755 −2.635 1.00 35.08 A ATOM 1987 CD ARG A 875 6.413 18.722 −2.844 1.00 40.15 A ATOM 1988 NE ARG A 875 7.555 19.234 −3.603 1.00 43.73 A ATOM 1989 CZ ARG A 875 8.448 20.094 −3.125 1.00 45.20 A ATOM 1990 NH1 ARG A 875 8.334 20.544 −1.883 1.00 45.87 A ATOM 1991 NH2 ARG A 875 9.457 20.502 −3.885 1.00 47.30 A ATOM 1992 C ARG A 875 2.477 20.028 −3.412 1.00 28.33 A ATOM 1993 O ARG A 875 1.965 19.100 −4.033 1.00 26.80 A ATOM 1994 N ASN A 876 2.756 21.199 −3.972 1.00 27.63 A ATOM 1995 CA ASN A 876 2.463 21.457 −5.375 1.00 27.11 A ATOM 1996 CB ASN A 876 3.223 22.703 −5.845 1.00 29.67 A ATOM 1997 CG ASN A 876 4.663 22.396 −6.237 1.00 32.23 A ATOM 1998 OD1 ASN A 876 5.558 23.221 −6.060 1.00 36.30 A ATOM 1999 ND2 ASP A 876 4.887 21.212 −6.786 1.00 33.53 A ATOM 2000 C ASN A 876 0.972 21.621 −5.632 1.00 25.93 A ATOM 2001 O ASN A 876 0.500 21.396 −6.746 1.00 26.98 A ATOM 2002 N HIS A 877 0.235 21.996 −4.592 1.00 24.62 A ATOM 2003 CA HIS A 877 1.206 22.203 −4.690 1.00 23.95 A ATOM 2004 CB HIS A 877 1.666 23.185 −3.605 1.00 25.91 A ATOM 2005 CG HIS A 877 1.103 24.566 −3.758 1.00 28.62 A ATOM 2006 CD2 HIS A 877 0.390 25.134 −4.760 1.00 29.02 A ATOM 2007 ND1 HIS A 877 1.268 25.548 −2.803 1.00 30.92 A ATOM 2008 CE1 HIS A 877 0.682 26.659 −3.212 1.00 32.07 A ATOM 2009 NE2 HIS A 877 0.142 26.434 −4.396 1.00 30.42 A ATOM 2010 C HIS A 877 1.987 20.893 −4.555 1.00 24.02 A ATOM 2011 O HIS A 877 3.169 20.821 −4.919 1.00 21.47 A ATOM 2012 N ARG A 878 1.342 19.860 −4.017 1.00 22.45 A ATOM 2013 CA ARG A 878 2.022 18.574 −3.858 1.00 20.77 A ATOM 2014 CE ARG A 878 1.196 17.618 −2.995 1.00 18.58 A ATOM 2015 CG ARG A 878 0.878 18.140 −1.609 1.00 17.53 A ATOM 2016 CD AEG A 878 0.163 17.267 −0.922 1.00 17.61 A ATOM 2017 NE ARG A 878 0.678 17.923 0.273 1.00 15.99 A ATOM 2018 CZ ARG A 878 1.898 17.746 0.763 1.00 17.79 A ATOM 2019 NH1 ARG A 878 2.743 16.913 0.165 1.00 18.10 A ATOM 2020 NH2 ARG A 878 2.282 18.440 1.830 1.00 20.88 A ATOM 2021 C ARG A 878 2.264 17.922 −5.208 1.00 20.33 A ATOM 2022 O ARG A 878 1.473 18.058 −6.137 1.00 21.44 A ATOM 2023 N PRO A 879 3.377 17.200 −5.334 1.00 19.46 A ATOM 2024 CD PRO A 879 4.395 16.893 −4.307 1.00 20.47 A ATOM 2025 CA PRO A 879 3.687 16.530 −6.592 1.00 18.32 A ATOM 2026 CB PRO A 879 5.116 16.050 −6.374 1.00 19.77 A ATOM 2027 CG PRO A 879 5.106 15.696 −4.907 1.00 18.07 A ATOM 2028 C PRO A 879 2.727 15.362 −6.801 1.00 18.71 A ATOM 2029 O PRO A 879 2.135 14.846 −5.849 1.00 17.95 A ATOM 2030 N LYS A 880 2.569 14.957 −8.051 1.00 18.17 A ATOM 2031 CA LYS A 880 1.705 13.835 −8.373 1.00 19.50 A ATOM 2032 CB LYS A 880 1.118 14.000 −9.775 1.00 20.53 A ATOM 2033 CG LYS A 880 0.082 15.125 −9.888 1.00 23.92 A ATOM 2034 CD LYS A 880 0.316 15.362 −11.334 1.00 26.32 A ATOM 2035 CB LYS A 880 1.444 16.384 −11.434 1.00 29.77 A ATOM 2036 NZ LYS A 880 1.732 16.761 −12.845 1.00 33.61 A ATOM 2037 C LYS A 880 2.545 12.572 −8.315 1.00 18.71 A ATOM 2038 O LYS A 880 3.775 12.637 −8.369 1.00 15.94 A ATOM 2039 N PHE A 881 1.887 11.421 −8.207 1.00 19.36 A ATOM 2040 CA PHE A 881 2.625 10.174 −8.148 1.00 18.63 A ATOM 2041 CB PHE A 881 1.679 8.980 −7.961 1.00 18.14 A ATOM 2042 CG PHE A 881 1.154 8.856 −6.561 1.00 15.85 A ATOM 2043 CD1 PHE A 681 0.182 9.091 −6.281 1.00 15.19 A ATOM 2044 CD2 PHE A 881 2.017 8.573 −5.503 1.00 14.91 A ATOM 2045 CE1 PHE A 881 0.661 9.055 −4.974 1.00 14.06 A ATOM 2046 CE2 PHE A 881 1.545 8.536 −4.186 1.00 14.78 A ATOM 2047 CZ PHE A 881 0.201 8.780 −3.923 1.00 16.56 A ATOM 2048 C PHE A 881 3.500 9.975 −9.365 1.00 18.17 A ATOM 2049 O PHE A 881 4.570 9.381 −9.266 1.00 17.98 A ATOM 2050 N GLY A 882 3.065 10.476 −10.517 1.00 17.95 A ATOM 2051 CA GLY A 882 3.879 10.329 −11.710 1.00 17.50 A ATOM 2052 C GLY A 882 5.173 11.112 −11.559 1.00 17.01 A ATOM 2053 O GLY A 882 6.256 10.660 −11.953 1.00 15.84 A ATOM 2054 N GLN A 883 5.066 12.295 −10.974 1.00 16.68 A ATOM 2055 CA GLN A 883 6.240 13.129 −10.776 1.00 18.91 A ATOM 2056 CE GLN A 883 5.813 14.551 −10.391 1.00 19.76 A ATOM 2057 CG GLN A 883 4.850 15.188 −11.387 1.00 25.47 A ATOM 2058 CD GLN A 883 4.415 16.571 −10.949 1.00 26.44 A ATOM 2059 OE1 GLN A 883 3.799 16.739 −9.896 1.00 24.34 A ATOM 2060 NE2 GLN A 883 4.748 17.577 −11.756 1.00 28.51 A ATOM 2061 C GLN A 883 7.116 12.519 −9.677 1.00 17.08 A ATOM 2062 O GLN A 883 8.336 12.625 −9.719 1.00 16.89 A ATOM 2063 N ILE A 884 6.484 11.872 −8.700 1.00 16.63 A ATOM 2064 CA ILE A 884 7.221 11.240 −7.612 1.00 15.31 A ATOM 2065 CB ILE A 884 6.267 10.698 −6.516 1.00 16.28 A ATOM 2066 CG2 ILE A 884 7.001 9.708 −5.594 1.00 15.49 A ATOM 2067 CG1 ILE A 884 5.700 11.869 −5.714 1.00 15.76 A ATOM 2068 CD1 ILE A 884 4.588 11.471 −4.743 1.00 19.15 A ATOM 2069 C ILE A 884 8.058 10.102 −8.166 1.00 14.47 A ATOM 2070 O ILE A 884 9.229 9.988 −7.839 1.00 14.80 A ATOM 2071 N VAL A 885 7.466 9.275 −9.024 1.00 13.59 A ATOM 2072 CA VAL A 885 8.223 8.177 −9.601 1.00 16.17 A ATOM 2073 CB VAL A 885 7.352 7.284 −10.502 1.00 16.96 A ATOM 2074 CG1 VAL A 885 8.216 6.248 −11.178 1.00 15.86 A ATOM 2075 CG2 VAL A 885 6.252 6.588 −9.676 1.00 16.66 A ATOM 2076 C VAL A 885 9.414 8.683 −10.416 1.00 19.15 A ATOM 2077 O VAL A 885 10.479 8.062 −10.417 1.00 16.03 A ATOM 2078 N ASN A 886 9.241 9.808 −11.110 1.00 19.66 A ATOM 2079 CA ASN A 886 10.320 10.343 −11.936 1.00 21.37 A ATOM 2080 CB ASN A 886 9.819 11.509 −12.793 1.00 23.10 A ATOM 2081 CD ASN A 886 8.698 11.102 −13.734 1.00 26.10 A ATOM 2082 OD1 ASN A 886 8.773 10.056 −14.398 1.00 26.24 A ATOM 2083 ND2 ASN A 886 7.654 11.926 −13.804 1.00 27.46 A ATOM 2084 C ASN A 886 11.500 10.807 −11.097 1.00 20.89 A ATOM 2085 O ASN A 886 12.655 10.562 −11.446 1.00 21.26 A ATOM 2086 N THR A 887 11.189 11.479 −9.995 1.00 19.17 A ATOM 2087 CA THR A 887 12.180 11.991 −9.069 1.00 20.28 A ATOM 2088 CE THR A 887 11.500 12.789 −7.939 1.00 22.23 A ATOM 2089 OG1 THR A 887 10.751 13.872 −8.504 1.00 24.34 A ATOM 2090 CG2 THR A 887 12.525 13.327 −6.968 1.00 22.10 A ATOM 2091 C THR A 887 12.961 10.838 −8.450 1.00 20.51 A ATOM 2092 O THR A 887 14.182 10.906 −8.339 1.00 20.72 A ATOM 2093 N LEU A 888 12.259 9.778 −8.055 1.00 17.54 A ATOM 2094 CA LEU A 888 12.926 8.619 −7.458 1.00 16.74 A ATOM 2095 CB LEU A 888 11.906 7.629 −6.882 1.00 13.99 A ATOM 2096 CG LEU A 888 11.102 8.102 −5.660 1.00 16.09 A ATOM 2097 CD1 LEU A 888 9.998 7.118 −5.344 1.00 12.23 A ATOM 2098 CD2 LEU A 888 12.037 8.236 −4.444 1.00 15.84 A ATOM 2099 C LEU A 888 13.791 7.939 −8.507 1.00 17.83 A ATOM 2100 O LEU A 888 14.914 7.509 −8.215 1.00 16.99 A ATOM 2101 N ASP A 889 13.278 7.846 −9.731 1.00 18.45 A ATOM 2102 CA ASP A 889 14.047 7.231 −10.809 1.00 19.88 A ATOM 2103 CB ASP A 889 13.216 7.089 −12.092 1.00 20.92 A ATOM 2104 CG ASP A 889 12.212 5.954 −12.031 1.00 24.40 A ATOM 2105 OD1 ASP A 889 12.496 4.901 −11.417 1.00 23.95 A ATOM 2106 OD2 ASP A 889 11.127 6.106 −12.620 1.00 26.43 A ATOM 2107 C ASP A 889 15.303 8.053 −11.128 1.00 20.04 A ATOM 2108 O ASP A 889 16.341 7.491 −11.459 1.00 20.12 A ATOM 2109 N LYS A 890 15.221 9.377 −11.035 1.00 20.98 A ATOM 2110 CA LYS A 890 16.398 10.193 −11.320 1.00 24.03 A ATOM 2111 CB LYS A 890 16.042 11.679 −11.353 1.00 23.49 A ATOM 2112 CD LYS A 890 15.102 12.062 −12.480 0.00 24.55 A ATOM 2113 CD LYS A 890 14.792 13.544 −12.453 0.00 25.01 A ATOM 2114 CE LYS A 890 13.901 13.935 −13.615 0.00 25.39 A ATOM 2115 NZ LYS A 890 13.587 15.388 −13.598 0.00 25.67 A ATOM 2116 C LYS A 890 17.455 9.935 −10.255 1.00 23.54 A ATOM 2117 O LYS A 890 18.644 9.911 −10.555 1.00 23.88 A ATOM 2118 N MET A 891 17.014 9.744 −9.012 1.00 23.82 A ATOM 2119 CA MET A 891 17.939 9.457 −7.913 1.00 22.98 A ATOM 2120 CB MET A 891 17.192 9.425 −6.573 1.00 22.51 A ATOM 2121 CD MET A 891 16.487 10.746 −6.206 1.00 19.86 A ATOM 2122 SD MET A 891 15.428 10.557 −4.742 1.00 22.11 A ATOM 2123 CE MET A 891 15.002 12.246 −4.390 1.00 18.78 A ATOM 2124 C MET A 891 18.639 8.120 −8.163 1.00 23.81 A ATOM 2125 O MET A 891 19.853 8.009 −7.996 1.00 23.38 A ATOM 2126 N ILE A 892 17.874 7.113 −8.581 1.00 22.60 A ATOM 2127 CA ILE A 892 18.451 5.806 −8.853 1.00 23.72 A ATOM 2128 CS ILE A 892 17.362 4.765 −9.203 1.00 22.69 A ATOM 2129 CG2 ILE A 892 18.001 3.453 −9.665 1.00 21.79 A ATOM 2130 CG1 ILE A 892 16.501 4.487 −7.969 1.00 21.70 A ATOM 2131 CD1 ILE A 892 15.347 3.569 −8.236 1.00 21.58 A ATOM 2132 C ILE A 892 19.454 5.892 −10.004 1.00 25.56 A ATOM 2133 O ILE A 892 20.508 5.264 −9.964 1.00 24.56 A ATOM 2134 N ARG A 893 19.126 6.672 −11.029 1.00 27.68 A ATOM 2135 CA ARG A 893 20.006 6.826 −12.183 1.00 28.93 A ATOM 2136 CS ARG A 893 19.246 7.486 −13.338 1.00 29.77 A ATOM 2137 CG ARG A 893 18.033 6.702 −13.801 0.00 30.52 A ATOM 2138 CD ARG A 893 17.167 7.518 −14.745 0.00 31.20 A ATOM 2139 NE ARG A 893 16.022 6.747 −15.220 0.00 31.76 A ATOM 2140 CZ ARG A 893 15.065 7.231 −16.006 0.00 32.04 A ATOM 2141 NH1 ARG A 893 15.109 8.492 −16.413 0.00 32.22 A ATOM 2142 NH2 ARG A 893 14.065 6.449 −16.388 0.00 32.22 A ATOM 2143 C ARG A 893 21.237 7.659 −11.828 1.00 28.29 A ATOM 2144 O ARG A 893 22.304 7.472 −12.410 1.00 30.73 A ATOM 2145 N ASN A 894 21.090 8.574 −10.873 1.00 27.77 A ATOM 2146 CA ASN A 894 22.206 9.421 −10.454 1.00 28.66 A ATOM 2147 CS ASN A 894 21.928 10.883 −10.791 1.00 32.18 A ATOM 2148 CG ASN A 894 21.446 11.064 −12.204 1.00 35.93 A ATOM 2149 OD2 ASN A 894 20.309 10.708 −12.536 1.00 38.24 A ATOM 2150 ND2 ASN A 894 22.305 11.613 −13.056 1.00 37.07 A ATOM 2151 C ASN A 894 22.444 9.295 −8.960 1.00 27.18 A ATOM 2152 O ASN A 894 22.256 10.257 −8.205 1.00 24.38 A ATOM 2153 N PRO A 895 22.878 8.102 −8.517 1.00 27.24 A ATOM 2154 CD PRO A 895 23.287 6.996 −9.402 1.00 27.14 A ATOM 2155 CA PRO A 895 23.162 7.774 −7.116 1.00 27.82 A ATOM 2156 CS PRO A 895 23.990 6.496 −7.222 1.00 27.28 A ATOM 2157 CG PRO A 895 23.441 5.847 −8.435 1.00 29.74 A ATOM 2158 C PRO A 895 23.888 8.859 −6.324 1.00 27.80 A ATOM 2159 O PRO A 895 23.705 8.974 −5.112 1.00 26.04 A ATOM 2160 N ASN A 896 24.718 9.655 −6.988 1.00 29.72 A ATOM 2161 CA ASN A 896 25.426 10.694 −6.257 1.00 31.84 A ATOM 2162 CB ASN A 896 26.449 11.392 −7.152 1.00 35.12 A ATOM 2163 CG ASN A 896 27.619 10.495 −7.491 1.00 37.45 A ATOM 2164 OD1 ASN A 896 28.189 9.842 −6.610 1.00 37.32 A ATOM 2165 ND2 ASN A 896 27.988 10.455 −8.769 1.00 38.75 A ATOM 2166 C ASN A 896 24.471 11.715 −5.652 1.00 31.58 A ATOM 2167 O ASN A 896 24.789 12.337 −4.642 1.00 32.05 A ATOM 2168 N SER A 897 23.295 11.876 −6.250 1.00 31.96 A ATOM 2169 CA SER A 897 22.322 12.828 −5.724 1.00 31.92 A ATOM 2170 CS SER A 897 21.100 12.903 −6.639 1.00 32.67 A ATOM 2171 OG SER A 897 20.427 11.657 −6.699 1.00 32.92 A ATOM 2172 C SER A 897 21.872 12.442 −4.320 1.00 32.25 A ATOM 2173 O SER A 897 21.288 13.253 −3.601 1.00 32.16 A ATOM 2174 N LEU A 898 22.150 11.200 −3.939 1.00 32.39 A ATOM 2175 CA LEU A 898 21.767 10.684 −2.629 1.00 33.14 A ATOM 2176 CS LEU A 898 21.338 9.223 −2.755 1.00 31.76 A ATOM 2177 CG LEU A 898 20.167 8.938 −3.702 1.00 30.43 A ATOM 2178 CD1 LEU A 898 20.050 7.442 −3.949 1.00 28.81 A ATOM 2179 CD2 LEU A 898 18.886 9.489 −3.101 1.00 29.32 A ATOM 2180 C LEU A 898 22.915 10.791 −1.633 1.00 35.96 A ATOM 2181 O LEU A 898 22.780 10.410 −0.466 1.00 35.50 A ATOM 2182 N LYS A 899 24.049 11.304 −2.100 1.00 37.16 A ATOM 2183 CA LYS A 899 25.218 11.453 −1.245 1.00 39.32 A ATOM 2184 CB LYS A 899 26.458 11.783 −2.083 1.00 39.91 A ATOM 2185 CG LYS A 899 26.875 10.675 −3.035 1.00 40.95 A ATOM 2186 CD LYS A 899 27.176 9.392 −2.279 1.00 42.25 A ATOM 2187 CE LYS A 899 27.521 8.254 −3.230 1.00 43.26 A ATOM 2188 NZ LYS A 899 27.655 6.962 −2.498 1.00 43.52 A ATOM 2189 C LYS A 899 24.996 12.540 −0.204 1.00 39.53 A ATOM 2190 O LYS A 899 25.502 12.451 0.913 1.00 39.99 A ATOM 2191 N ALA A 900 24.238 13.566 −0.574 1.00 40.31 A ATOM 2192 CA ALA A 900 23.952 14.672 0.332 1.00 41.45 A ATOM 2193 CB ALA A 900 23.297 15.816 −0.436 1.00 42.71 A ATOM 2194 C ALA A 900 23.047 14.225 1.477 1.00 42.06 A ATOM 2195 O ALA A 900 23.462 14.222 2.638 1.00 43.54 A ATOM 2196 O HOH A 1 14.457 −2.301 −3.629 1.00 11.91 A ATOM 2197 O HOH A 2 −4.397 11.098 3.237 1.00 16.01 A ATOM 2198 O HOH A 3 −4.918 7.667 −5.486 1.00 16.02 A ATOM 2199 O HOH A 4 −18.623 −6.192 −4.002 1.00 15.98 A ATOM 2200 O HOH A 5 −1.021 11.333 −8.745 1.00 17.20 A ATOM 2201 O HOH A 6 2.429 1.976 9.154 1.00 11.10 A ATOM 2202 O HOH A 7 9.183 −2.818 −7.644 1.00 12.10 A ATOM 2203 O HOH A 8 −2.277 −6.184 −9.377 1.00 16.99 A ATOM 2204 O HOH A 9 −3.892 7.522 2.129 1.00 11.77 A ATOM 2205 O HOH A 10 −24.765 −1.312 −3.431 1.00 11.31 A ATOM 2206 O HOH A 11 −18.960 −7.652 −1.790 1.00 14.87 A ATOM 2207 O HOH A 12 1.251 −7.943 −7.973 1.00 15.91 A ATOM 2208 O HOH A 13 −5.135 9.220 4.569 1.00 25.85 A ATOM 2209 O HOH A 14 0.868 13.830 8.869 1.00 19.70 A ATOM 2210 O HOH A 15 −4.469 −6.600 −8.030 1.00 17.02 A ATOM 2211 O HOH A 16 −23.949 2.424 −2.051 1.00 16.20 A ATOM 2212 O HOH A 17 16.570 −0.194 −6.147 1.00 20.96 A ATOM 2213 O HOH A 18 0.212 10.493 −11.249 1.00 32.03 A ATOM 2214 O HOH A 19 18.352 −5.806 −3.576 1.00 21.26 A ATOM 2215 O HOH A 20 −1.189 18.011 −6.297 1.00 21.54 A ATOM 2216 O HOH A 21 −2.174 −6.079 3.946 1.00 21.58 A ATOM 2217 O HOH A 22 2.660 2.991 −12.285 1.00 10.78 A ATOM 2218 O HOH A 23 6.194 0.599 12.618 1.00 26.49 A ATOM 2219 O HOH A 24 6.270 2.873 10.787 1.00 20.59 A ATOM 2220 O HOH A 25 −30.350 −2.848 −5.086 1.00 21.38 A ATOM 2221 O HOH A 26 −5.973 10.069 1.056 1.00 21.49 A ATOM 2222 O HOH A 27 7.351 −13.578 −1.294 1.00 24.35 A ATOM 2223 O HOH A 28 −16.655 −18.205 6.142 1.00 32.77 A ATOM 2224 O HOH A 29 −23.065 −6.820 10.522 1.00 24.13 A ATOM 2225 O HOH A 30 14.170 15.934 −4.146 1.00 22.96 A ATOM 2226 O HOH A 31 −5.570 −1.784 −15.428 1.00 26.29 A ATOM 2227 O HOH A 32 −12.382 −1.657 −13.385 1.00 22.13 A ATOM 2228 O HOH A 33 11.773 −2.825 −3.978 1.00 17.40 A ATOM 2229 O HOH A 34 24.033 2.469 1.013 1.00 28.57 A ATOM 2230 O HOH A 35 5.376 16.007 8.519 1.00 24.65 A ATOM 2231 O HOH A 36 −9.608 −13.304 −9.571 1.00 27.67 A ATOM 2232 O HOH A 37 −5.225 −8.904 −9.144 1.00 18.25 A ATOM 2233 O HOH A 38 11.257 −0.407 −7.511 1.00 29.30 A ATOM 2234 O HOH A 39 0.499 −15.307 6.874 1.00 26.00 A ATOM 2235 O HOH A 40 −11.598 −8.243 3.065 1.00 18.53 A ATOM 2236 O HOH A 41 2.939 23.776 3.343 1.00 30.46 A ATOM 2237 O HOH A 42 −10.147 −9.966 7.681 1.00 26.73 A ATOM 2238 O HOH A 43 9.258 −2.252 −4.749 1.00 18.60 A ATOM 2239 O HOH A 44 −7.990 1.495 0.072 1.00 32.79 A ATOM 2240 O HOH A 45 −21.791 −2.653 3.395 1.00 30.17 A ATOM 2241 O HOH A 46 −12.258 8.515 −1.865 1.00 32.59 A ATOM 2242 O HOH A 47 17.934 −29.751 44.878 1.00 37.91 A ATOM 2243 O HOH A 48 −5.849 14.783 −6.753 1.00 25.08 A ATOM 2244 O HOH A 49 −0.415 −15.909 −10.041 1.00 30.96 A ATOM 2245 O HOH A 50 2.276 −3.698 10.859 1.00 31.49 A ATOM 2246 O HOH A 51 13.707 −1.745 14.947 1.00 26.81 A ATOM 2247 O HOH A 52 −11.484 5.994 −4.734 1.00 28.94 A ATOM 2248 O HOH A 53 15.597 8.025 12.778 1.00 25.87 A ATOM 2249 O HOH A 54 −12.859 −0.373 −16.318 1.00 38.15 A ATOM 2250 O HOH A 55 −21.136 −9.246 −1.882 1.00 23.94 A ATOM 2251 O HOH A 56 10.996 16.960 15.947 1.00 36.67 A ATOM 2252 O HOH A 57 −6.591 9.869 −9.281 1.00 26.49 A ATOM 2253 O HOH A 58 13.911 −11.174 2.291 1.00 30.38 A ATOM 2254 O HOH A 59 −9.562 −10.942 −10.916 1.00 27.88 A ATOM 2255 O HOH A 60 4.745 −19.626 −5.080 1.00 29.55 A ATOM 2256 O HOH A 61 −1.717 −8.359 −10.786 1.00 24.62 A ATOM 2257 O HOH A 62 −10.559 −3.268 −13.949 1.00 24.21 A ATOM 2258 O HOH A 63 −0.660 15.194 −5.517 1.00 22.53 A ATOM 2259 O HOH A 64 9.037 −0.135 −9.783 1.00 36.19 A ATOM 2260 O HOH A 65 −23.460 −16.827 8.631 1.00 29.91 A ATOM 2261 O HOH A 66 −24.192 −1.276 5.295 1.00 27.96 A ATOM 2262 O HOH A 67 −16.353 4.624 −11.962 1.00 32.05 A ATOM 2263 O HOH A 68 −17.396 3.801 −9.450 1.00 28.58 A ATOM 2264 O HOH A 69 10.752 −11.093 7.051 1.00 37.06 A ATOM 2265 O HOH A 70 1.620 −15.965 −4.603 1.00 24.63 A ATOM 2266 O HOH A 71 −8.238 12.427 −6.673 1.00 33.82 A ATOM 2267 O HOH A 72 −16.577 −14.805 −9.290 1.00 29.62 A ATOM 2268 O HOH A 73 9.083 −13.189 −4.221 1.00 35.45 A ATOM 2269 O HOH A 74 10.287 7.919 −14.356 1.00 33.56 A ATOM 2270 O HOH A 75 −20.538 −21.060 2.242 1.00 45.67 A ATOM 2271 O HOH A 76 −1.640 14.388 9.613 1.00 30.93 A ATOM 2272 O HOH A 77 40.049 −7.010 13.782 1.00 30.14 A ATOM 2273 O HOH A 78 18.418 12.809 −8.404 1.00 37.11 A ATOM 2274 O HOH A 79 −25.942 −2.805 −10.608 1.00 34.88 A ATOM 2275 0 HOH A 80 16.293 −4.489 17.257 1.00 25.34 A ATOM 2276 O HOH A 81 −16.209 −8.340 11.406 1.00 40.96 A ATOM 2277 O HOH A 82 11.439 19.084 12.127 1.00 33.B2 A ATOM 2278 O HOH A 83 20.159 2.221 5.570 1.00 28.54 A ATOM 2279 O HOH A 84 −13.713 5.569 −10.421 1.00 29.53 A ATOM 2280 O HOH A 85 −7.262 16.174 −0.684 1.00 29.54 A ATOM 2281 O HOH A 86 9.742 −10.617 −7.415 1.00 25.62 A ATOM 2282 O HOH A 87 −20.632 0.152 7.971 1.00 39.94 A ATOM 2283 O HOH A 88 1.339 18.421 −9.397 1.00 43.65 A ATOM 2284 0 HOH A 89 −4.943 13.752 20.778 1.00 37.74 A ATOM 2285 O HOH A 90 −3.157 10.534 20.505 1.00 40.33 A ATOM 2286 O HOH A 91 20.471 14.004 −1.018 1.00 22.59 A ATOM 2287 O HOH A 92 −3.126 −6.909 11.806 1.00 31.06 A ATOM 2288 O HOH A 93 −14.587 −14.560 24.267 1.00 48.31 A ATOM 2289 O HOH A 94 4.029 −14.349 32.347 1.00 56.74 A ATOM 2290 O HOH A 95 7.949 −15.761 −2.076 1.00 40.76 A ATOM 2291 O HOH A 96 −2.357 13.362 −6.866 1.00 25.37 A ATOM 2292 O HOH A 97 0.273 12.223 −13.491 1.00 30.12 A ATOM 2293 O HOH A 98 23.889 −3.917 11.357 1.00 25.67 A ATOM 2294 0 HOH A 99 −4.748 −9.020 −11.939 1.00 46.38 A ATOM 2295 O HOH A 100 −1.430 −10.359 −13.316 1.00 31.41 A ATOM 2296 O HOH A 101 10.739 −23.422 −9.199 1.00 39.50 A ATOM 2297 O HOH A 102 −3.937 14.980 −8.334 1.00 24.93 A ATOM 2298 O HOH A 103 −7.054 −10.787 −10.296 1.00 33.68 A ATOM 2299 O HOH A 104 13.492 0.660 13.579 1.00 31.04 A ATOM 2300 O HOH A 105 −6.920 −14.447 −11.281 1.00 45.39 A ATOM 2301 O HOH A 106 13.348 22.708 2.254 1.00 36.30 A ATOM 2302 O HOH A 107 5.408 −11.711 −5.405 1.00 31.10 A ATOM 2303 O HOH A 108 18.256 −2.341 15.534 1.00 28.95 A ATOM 2304 O HOH A 109 −8.503 0.787 3.249 1.00 41.16 A ATOM 2305 O HOH A 110 14.317 3.040 −11.205 1.00 42.00 A ATOM 2306 O HOH A 111 11.881 17.271 −4.308 1.00 37.83 A ATOM 2307 O HOH A 112 19.020 15.966 5.172 1.00 45.54 A ATOM 2308 O HOH A 113 0.998 −12.806 −8.453 1.00 43.81 A ATOM 2309 O HOH A 114 13.315 −10.545 8.002 1.00 33.76 A ATOM 2310 O HOH A 115 −10.798 3.629 0.360 1.00 29.35 A ATOM 2311 O HOH A 116 26.244 9.778 1.025 1.00 38.48 A ATOM 2312 O HOH A 117 −18.933 −5.540 7.951 1.00 21.69 A ATOM 2313 O HOH A 118 −2.346 9.089 14.123 1.00 28.55 A ATOM 2314 O HOH A 119 12.331 −3.683 −6.285 1.00 28.50 A ATOM 2315 O HOH A 120 17.652 7.204 6.269 1.00 33.34 A ATOM 2316 O HOH A 121 −20.972 −5.394 10.153 1.00 29.22 A ATOM 2317 O HOH A 122 1.126 −29.138 3.663 1.00 54.55 A ATOM 2318 O HOH A 123 19.859 5.269 4.518 1.00 48.81 A ATOM 2319 O HOH A 124 16.235 −4.760 13.356 1.00 24.74 A ATOM 2320 O HOH A 125 −1.781 27.895 −1.429 1.00 49.94 A ATOM 2321 O HOH A 126 0.978 3.103 −14.170 1.00 33.01 A ATOM 2322 O HOH A 127 23.932 8.429 −15.415 1.00 43.20 A ATOM 2323 O HOH A 128 −15.975 −7.260 14.283 1.00 35.46 A ATOM 2324 O HOH A 129 −5.663 −12.681 1.284 1.00 25.44 A ATOM 2325 O HOH A 130 −9.888 −12.927 7.395 1.00 35.96 A ATOM 2326 O HOH A 131 25.472 3.261 −1.345 1.00 31.42 A ATOM 2327 O HOH A 132 0.225 −4.710 9.057 1.00 40.52 A ATOM 2328 O HOH A 133 1.153 −8.592 −10.392 1.00 41.49 A ATOM 2329 O HOH A 134 0.318 −2.638 −15.320 1.00 36.09 A ATOM 2330 O HOH A 135 −6.483 17.186 −5.700 1.00 31.77 A ATOM 2331 O HOH A 136 −11.747 5.541 −2.116 1.00 37.63 A ATOM 2332 O HOH A 137 3.033 5.741 −16.256 1.00 60.91 A ATOM 2333 O HOH A 138 15.857 −9.756 3.393 1.00 42.40 A ATOM 2334 O HOH A 139 1.315 24.812 0.302 1.00 37.92 A ATOM 2335 O HOH A 140 18.429 −8.563 6.665 1.00 40.06 A ATOM 2336 O HOH A 141 8.361 17.182 −5.869 1.00 35.77 A ATOM 2337 O HOH A 142 −3.830 −1.160 8.545 1.00 30.75 A ATOM 2338 O HOH A 143 −11.080 −0.626 −21.190 1.00 42.20 A ATOM 2339 O HOH A 144 −25.620 −5.418 −10.124 1.00 24.22 A ATOM 2340 N9 ANE A 400 −0.759 −10.830 5.271 1.00 36.71 A ATOM 2341 C8 ANE A 400 −1.712 −10.252 4.469 1.00 37.40 A ATOM 2342 N7 ANE A 400 −1.529 −10.440 3.198 1.00 37.33 A ATOM 2343 Cs ANE A 400 −0.400 −11.181 3.134 1.00 37.65 A ATOM 2344 C6 ANE A 400 0.318 −11.704 2.059 1.00 38.63 A ATOM 2345 N6 ANE A 400 −0.086 −11.507 0.797 1.00 39.54 A ATOM 2346 M1 ANE A 400 1.443 −12.423 2.375 1.00 37.38 A ATOM 2347 C2 ANE A 400 1.792 −12.580 3.654 1.00 38.46 A ATOM 2348 N3 ANE A 400 1.207 −12.139 4.749 1.00 39.20 A ATOM 2349 C4 ANE A 400 0.099 −11.435 4.400 1.00 37.67 A END

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1. An isolated binding pocket of a receptor tyrosine kinase (RTK) that regulates the kinase domain of the receptor tyrosine kinase.
 2. An isolated binding pocket as claimed in claim 1 wherein the RTK is an Eph receptor, preferably an EphB2 receptor.
 3. Molecules or molecular complexes that comprise all or parts of either one or more of a binding pocket as claimed in claim 1 or 2, or a homolog of the binding pocket that has similar structure and shape.
 4. A crystal comprising a binding pocket of an RTK that regulates the kinase domain of the RTK.
 5. A crystal as claimed in claim 4 wherein the binding pocket is in an autoinhibited state.
 6. A crystal comprising a juxtamembrane region and/or kinase domain of an RTK, or part thereof.
 7. A crystal formed by a juxtamembrane region and a kinase domain of an RTK in an autoinhibited state.
 8. A crystal comprising a binding pocket of an RTK that regulates the kinase domain of the RTK, in association with a ligand.
 9. A crystal comprising a binding pocket of an RTK as claimed in claim 1 or 2 complexed or associated with a ligand.
 10. A crystal as claimed in claim 9 wherein the ligand is a nucleotide or analogue thereof, a substrate or analogue thereof, a cofactor, and/or heavy metal atom.
 11. A crystal as claimed in claim 9 wherein the ligand is a modulator of the activity of an RTK.
 12. A crystal as claimed in any of the preceding claims wherein the shape and structure of the binding pocket is defined by one or more atomic interactions or enzyme atomic contacts in Table
 2. 13. A crystal comprising a binding pocket of an Eph receptor.
 14. A crystal comprising a binding pocket of an Eph receptor and a nucleotide or analogue thereof, from which it is possible to derive structural data for the nucleotide.
 15. A crystal according to any preceding claim wherein the Eph receptor is derivable from a human cell.
 16. A crystal according to any preceding claim, wherein the an Eph receptor is EphB2.
 17. A crystal according to any preceding claim wherein the crystal comprises a binding pocket of an Eph receptor having a mutation in the part of the enzyme which is involved in phosphorylation.
 18. A crystal according to any preceding claim wherein the crystal comprises a binding pocket of an Eph receptor having a mutation in one or more tyrosine residues.
 19. A crystal according to any preceding claim wherein the binding pocket is in association with a cofactor.
 20. A crystal according to any preceding claim having the structural coordinates shown in Table
 3. 21. A model of a binding pocket of an RTK made using a crystal according to any preceding claim.
 22. A model of: (a) a binding pocket of an RTK that is involved in maintaining an autoinhibited state or active state of an RTK or regulates the kinase domain of an RTK; and (b) a modification of the model of (a).
 23. A model of a binding pocket of the present invention that substantially represents the structural coordinates specified in Table 3
 24. A computer-readable medium having stored thereon a crystal or model according to any of the preceding claims.
 25. A method of determining the secondary and/or tertiary structures of a polypeptide comprising the step of using a crystal or model according to any of the preceding claims.
 26. A method of screening for a ligand capable of associating with a binding pocket and/or inhibiting or enhancing the atomic contacts of interactions in a binding pocket, comprising the use of a crystal or model according to any of the preceding claims.
 27. A ligand identified by a method according to claim
 26. 28. A ligand identified by a method according to claim 26 that is a modulator capable of modulating the activity of the RTK.
 29. A method of identifying a modulator of an RTK comprising determining if a test agent inhibits or potentiates an autoinhibited state or active state of a kinase domain of the RTK.
 30. A method as claimed in claim 29 comprising one or more of the following additional steps: (a) testing whether the modulator is a modulator of the activity of a RTK, preferably testing the activity of the modulator in cellular assays and animal model assays; (b) modifying the modulator; (c) optionally rerunning steps (a) or (b); and (d) preparing a pharmaceutical composition comprising the modulator.
 31. A method of conducting a drug discovery business comprising: (a) providing one or more systems employing the atomic interactions, atomic contacts, or structural coordinates of a binding pocket of an RTK, for identifying agents by their ability to inhibit or potentiate the atomic interactions or atomic contacts of a binding pocket; and (b) conducting therapeutic profiling of agents identified in step (a), or further analogs thereof, for efficacy and toxicity in animals; and (d) formulating a pharmaceutical preparation including one or more agents identified in step (b) as having an acceptable therapeutic profile.
 32. A method of conducting a drug discovery business comprising (a) providing one or more systems for identifying agents by their ability to inhibit or potentiate an autoinhibited state or active state of a kinase domain of an RTK; and (b) conducting therapeutic profiling of agents identified in step (a), or further analogs thereof, for efficacy and toxicity in animals; and (c) formulating a pharmaceutical preparation including one or more agents identified in step (b). as having an acceptable therapeutic profile.
 33. A method of conducting a target discovery business comprising: (a) providing one or more systems employing the atomic interactions, atomic contacts, or structural coordinates of a binding pocket of an RTK, for identifying agents by their ability to inhibit or potentiate the atomic interactions or atomic contacts, or providing one or more systems for identifying agents by their ability to inhibit or potentiate an autoinhibited state or active state of a kinase domain of an RTK; (b) optionally conducting therapeutic profiling of agents identified in step (a) for efficacy and toxicity in animals; and (c) licensing, to a third party, the rights for further drug development and/or sales for agents identified in step (a), or analogs thereof.
 34. A method for regulating the kinase domain of an RTK by changing a binding domain or pocket of a RTK that regulates the kinase domain, from an autoinhibited state to an active state or from an active state to an autoinhibited state
 35. A method for inhibiting kinase activity of an RTK comprising maintaining the RTK or a binding pocket thereof involved in regulating the kinase domain in an autoinhibited state, or potentiating an autoinhibited state for the RTK or binding pocket thereof involved in regulating the kinase domain.
 36. Use of a modulator according to any preceding claim in the manufacture of a medicament to treat and/or prevent a disease in a mammalian patient.
 37. A pharmaceutical composition comprising a ligand or modulator according to any preceding claim, and optionally a pharmaceutically acceptable carrier, diluent, excipient or adjuvant or any combination thereof.
 38. A method of treating and/or preventing a disease comprising administering a ligand, modulator, or pharmaceutical composition according to any preceding claim to a mammalian patient.
 39. A method of treating or preventing a condition or disease associated with an RTK in a cellular organism, comprising: (a) administering a pharmaceutical composition as claimed in claim 38; and (b) activating or inhibiting the RTK to treat or prevent the disease.
 40. A method for treating or preventing a condition or disease involving increased RTK activity comprising maintaining the RTK, or a binding pocket thereof involved in regulating the kinase domain of the RTK, in an autoinhibited state
 41. A crystal comprising an RTK binding pocket, substantially as described herein and with reference to the accompanying figures. 